Human tissue factor antibody and uses thereof

ABSTRACT

The invention relates to a humanized form of an antibody capable of preventing tissue factor (coagulation factor F3) signaling but which does not interfere with Factor VII binding or FX binding to tissue factor and does not prolong coagulation time. The antibody of the invention is useful in treating conditions, such as tumor progression, in which the associated cells express tissue factor and tissue factor signaling occurs.

CONTINUING DATA

This application is a divisional of U.S. patent application Ser. No. 13/398,881, filed Feb. 17, 2012, pending; which claims priority to U.S. Provisional Patent Application 61/452,674, filed Mar. 15, 2011. This application also is a divisional of U.S. patent application Ser. No. 13/803,887, filed Mar. 14, 2013, pending. Each of these applications is entirely incorporated by reference herein.

BACKGROUND

1. Field of the Invention

The invention relates to human adapted antibodies which bind human tissue factor, an antigen present on extra vascular tissues including tumor cells, which antibodies do not inhibit tissue factor mediated blood coagulation. The invention also relates to methods of using the antibody to treat conditions such as cancer that are associated with the presence and receptor functions of human tissue factor.

2. Discussion of the Field

Tissue Factor (TF), also known as coagulation factor III (F3), tissue thromboplastin, or CD142 is a transmembrane glycoprotein having a 219 amino acid extracellular domain comprising two fibronectin type III domains and a short intracellular domain with one serine residue capable of being phosphorylated. TF is the cellular receptor for FVII/FVIIa.

TF exhibits a tissue-specific distribution with high levels in the normal brain, lung and placenta and low levels in the spleen, thymus, skeletal muscle and liver in the form of a cellular receptor. It is also found in cell-derived microparticles and as an alternatively spliced soluble form. In addition to the expression in normal tissue, TF has been reported to be over-expressed in most major tumor types and in many tumor-derived cell lines (Ruf W J Thromb Haemost. 5:1584-1587, 2007; Milsom et al., Arterioscler Thromb Vasc Biol. 29: 2005-2014, 2009).

Coagulation of serum proteins in response to injury is an important physiological response to injury. Exposure of the blood to proteins including collagen (intrinsic pathway) and tissue factor (extrinsic pathway) initiates changes to blood platelets and the plasma protein fibrinogen, a clotting factor. Following damage to a blood vessel, factor VII (FVII) leaves the circulation and comes into contact with tissue factor (TF) expressed on tissue-factor-bearing cells (stromal fibroblasts and leukocytes), forming an activated TF-FVIIa complex. TF-FVIIa activates factor IX (FIX) and factor X (FX). FVII can be allosterically activated by TF and activated by thrombin, FXIa, plasmin, FXII and FXa. TF-FVIIa forms a ternary complex with FXa.

Tissue factor (TF) expression by nonvascular cells plays an essential role in hemostasis by activating blood coagulation. TF is further associated with processes distinct from hemostasis and directly related to functions at the surface of cells on which it is expressed. TF-dependent assembly of coagulation proteases on vascular and nonvascular cells activates protease activated receptors (PARs) which are G-protein-coupled receptors. Thus, the TF:VIIa complex is capable of inducing cell signaling, through PARs, primarily PAR2 (Camerer et al., Proc. Natl. Acad. Sci. USA 97:5255-5260, 2000; Riewald & Ruf, Proc. Natl. Acad. Sci. USA 98:7742-7747, 2001; Ruf et al, J Thromb Haemost 1: 1495-4503, 2003; Chen et al., Thromb Haemost 86: 334-45, 2001) contributing to tumorigenesis, angiogenesis, tumor progression, and metastasis.

The ternary complex TF/FVIIa/FXa is formed directly by the TF:VIIa complex acting on FX or indirectly after TF:VIIa cleavage of FIX to FIXa which can cleave FX to FXa. The TF/FVIIa/FXa complex formation may result in signaling or activate other receptors such as PAR1-4. TF/FVIIa/FXa complex formation leads to the induction of Interleukin-8 (IL-8), which can stimulate tumor cell migration (Hjortor et al., Blood 103:3029-3037, 2004). Both PAR1 and PAR2 are involved in tumor metastasis (Shi et al., Mol Cancer Res. 2:395-402, 2004), however, the activated binary and ternary complexes, TF-VIIa and TF-VIIa-FXa, are activators of PAR2 which also leads to cell signaling (Rao & Pendurthi, Arterioscler. Thromb. Vasc. Biol. 25:47-56, 2005). Therefore, it was of interest to determine whether the oncogenic role of tissue factor could be separated from the procoagulant role, which had also long been suspected to be involved in tumor migration, extravasation, and metastatic mechanisms.

Monoclonal antibodies such as those described by Morrisey (1988, Thromb Res 52(3): 247-261; U.S. Pat. No. 5,223,427) and Magdolen (1996 Biol Chem 379: 157-165) to tissue factor have been used to explore functional and immunological aspects of the ligand binding sites. Monoclonal antibodies capable of binding tissue factor can be used to block thrombotic events by interfering with the ability of TF to form or maintain the TF-VIIa complex or by blocking the ability of the complex to activate FX. Antibodies that bind to tissue factor and do not block coagulation are also known. Factor VIIa initiated TF signaling blocking but not coagulation blocking antibodies such as the antibody 10H10 have also been described (Ahamed et al. 2006 Proc Natl Acad Sci USA 103 (38): 13932-13937) and such antibodies have provided the opportunity to study the role and utility of an agent with such activity in the treatment of solid tumors (Versteeg, et al 2008 Blood 111(1): 190-199). Ruf et al, in published application WO2007056352A3 discloses methods and compositions for inhibiting tissue factor signaling without interfering with hemostatis in a patient.

As cancer progression is a multifaceted process, a therapeutic candidate which is a TF binding antibody capable of blockade of oncogenic, metastatic, angiogenic, and anti-apoptotic functions on tumor cells while not interfering with hemostasis in a patient would be desirable.

SUMMARY OF THE INVENTION

The present invention provides a human adapted anti-human tissue factor specific antibody for use as a human therapeutic which retains the binding epitope of the murine antibody 10H10, which antibody does not compete with tissue factor for FVIIa binding and therefore does not substantially block the procoagulant, amidolytic activity of the TF-VIIa complex but which does block TF-VIIa mediated signaling and downstream oncogenic effects such as cytokine IL-8 release.

The human adapted antibody of the invention is constructed of human IgG variable domain frameworks in combination with CDR variant residues as determined by referring to the sequence of the 10H10 murine antibody CDR sequences and as represented as SEQ ID NO: 6-11 and 27. Human frameworks FR1 and FR2 and FR3, combined with the CDRs and CDR variants, with FR4, are provided which allow the assembly of antibody binding domains with the immunospecificity of the murine antibody 10H10. In one embodiment of the invention, the six CDR sequences represented by SEQ ID NO: 6-11 or as the group represented by SEQ ID NO: 6, 8-11, and 27 are combined with human germline FRs, defined as the non-CDR positions of a human IgG variable domain, selected so that the binding affinity of 10H10 for human TF is retained. In one aspect, the human HC variable region FRs are derived from an IGHV gene family 1, 3 or 5 member as represented by the IMGT database. In one aspect, the human LC variable region FRs are derived from a human IGKV gene family 2 or 4 member. In one embodiment, antibody Fv (HC variable region paired with a LC variable region) comprise an HC variable domain selected from SEQ ID NO: 12-21 and a LC variable domain selected from SEQ ID NO: 22-26.

In a particular embodiment, the human FRs forming an antibody Fv (HC variable region paired with a LC variable region) comprise IGHV5 and IGKV2 FRs. The antibody of the invention comprises an HC variable domain having the H-CDR3 of SEQ ID NO: 8; an H-CDR1 having a sequence selected from SEQ ID NO: 6, and 62-83; an H-CDR2 having a sequence selected from SEQ ID NO: 7, 27, and 84-107; and an HC FR4 region, optionally, selected from IGVJ4 (SEQ ID NO: 60) or a variant thereof. The antibodies of the invention further comprise those having an LC variable domain having an L-CDR1 having a sequence selected from SEQ ID NO: 9, 108-116; an L-CDR2 having a sequence selected from SEQ ID NO: 10 and 117-120; and an L-CDR3 having a sequence selected from SEQ ID NO: 11 and 121-128; and a LC FR4 region, optionally, selected from IGKJ2 (SEQ ID NO: 61) or a variant thereof. In a specific embodiment, the human framework sequences are derived from IGHV5_a and the created variable domain comprises a sequence selected from SEQ ID NO: 19, 129-155. In another embodiment, the human framework sequences are derived from IGKV2D40_O1 and the created variable domain comprises a sequence selected from SEQ ID NO: 23, 156-163.

The antibodies of the present invention can be represented in one form as antibodies having a binding domain derived from IGHV5_a frameworks, defined as non-CDR positions, an H-CDR3 having the sequence SGYYGNSGFAY (SEQ ID NO: 8), wherein the sequences at the H-CDR-1 positions is given by the formula:

H-CDR1 (SEQ ID NO: 83) GYTFX₁X₂X₃WIE (I)

where X1 is selected is selected from A, D, G, I, L, N, P, R, S, T, V, and Y; X2 is selected from A, P, S, and T and X3 is selected from F, H, and Y; or the sequence may be GFTFITYWIA (SEQ ID NO: 81); and the sequence at the H-CDR2 position is given by the formula:

H-CDR2 (SEQ ID NO: 107) DIX₁PGX₂GX₃TX₄ (II)

where X1 is selected from 1 and L, X2 is selected from S and T, X3 is selected from A, F, H, and w; and X4 is selected from D, H, I, L, and N; except in H189 where H-CDR2 is DILPASSSTN (SEQ ID NO: 105).

The antibodies of the invention are represented as antibodies having a binding domain derived from IGKV2D40_O1 frameworks, defined as non-CDR positions, and wherein the sequences at the L-CDR-1 and/or LCDR-2, and L-CDR3 have the sequences given by the formulas:

L-CDR1 (SEQ ID NO: 116) KSSQSLLX₁X₂X₃ X₄Q X₅NYLT (III)

where X1 is selected from F, P, S, T, W, and Y; X2 is selected from F, S, T, R, and V; X3 is selected from A, G, P, S, W, Y, AND V; X4 is selected from G, N, and T; X5 is selected from K, R, and S;

L-CDR2 (SEQ ID NO: 120) X₁ASTRX₂S (IV)

where X1 is selected from H and W; X2 is selected from D, E and S;

L-CDR3 (SEQ ID NO: 128) QNDX₁X₂X₃PX₄T (V)

where X1 is selected from D, F, and L; X2 is selected from S, T, and Y; X3 is selected from W, and Y; X4 is selected from L, and M.

Thus, the antibody heavy chain and light chain CDR residues are substantially modified from the murine CDRs of 10H10. For instance, in accordance with the description set forth above, the antibody heavy chain can be only 70% (3/10 residues altered in CDR1), and 60% (4/10 residues altered in CDR2) similar to the murine CDRs of 10H10 (CDR 3 is unchanged). The light chain CDR residues are only 71% (5/17 changed)), (71%) (2/7 changed), or 55% (4/9 changed) similar to the murine CDRs of 10H10.

The invention further provides human adapted antibodies that compete for binding to human tissue factor and thus bind to substantially the same epitope on human TF-ECD as the murine 10H10 antibody. The invention further provides methods of using such antibodies to treat a human subject suffering from a condition in which TF-expression and local bioactivity resulting from the TF-expression is directly or indirectly related to the condition to be treated.

The invention further provides methods for preparing the antibodies as well as pharmaceutically acceptable preparations of the antibodies, a container comprising the preparation, and a kit comprising the container wherein the antibody of the invention is made available for the methods of use to treat a human subject.

DESCRIPTION OF THE DRAWINGS

FIG. 1 shows the epitope revealed by X-ray diffraction analysis of a co-crystal of 10H10 Fab or with a human adapted variant (M1593 Fab) and human TF-ECD residues 5-208, where the two contact residues that were changed in M1593 H-CDR1 (T31P) and HCDR-2 (S57F) are shown.

FIG. 2 is an alignment of the amino acid residues of human (SEQ ID NO: 1, 1-219), cyno (SEQ ID NO: 2, 1-220), and mouse TF-ECD (SEQ ID NO: 3, 1-221) showing residue positions contacted by the murine antibody TF8-5G9 (Huang et al. 1998 J Mol Biol 275:873-94) and 10H10 and those residues known to be in contact with the coagulation factors FVII/VIIa and FX.

FIG. 3 shows the three dimensional projection of human TF-ECD with the areas indicated contacted by the paratopes of 5G9 and 10H10 as well as the coagulation factors FVII and FX, where only residues L104 and T197 are contacted by both 10H10 and FX.

FIG. 4 shows an alignment of the amino acid sequences of the heavy chain (upper alignment) and light chain (lower alignment) variable domains of the murine antibody 10H10 (SEQ ID NO: 4 and 5, respectively), the human framework adapted sequences of antibody M59 (SEQ ID NO: 19 and 23, respectively) and, two selected affinity matured variable domain sequences H116 (SEQ ID NO: 133) and H171 (SEQ ID NO: 139).

FIG. 5 shows the relative percent inhibition by the 27 affinity matured mAbs to FVIIa-induced IL-8 release at 0.24 ug/ml by MDB-MB-231 breast cancer cells compared to the isotype control B37.

FIG. 6 shows a plot of tumor volume over days post-implantation of MDA-MB231 tumor cells in immunocompromised mice where the group dosed with M1593 reduced growth of an established tumor.

FIG. 7 shows a plot of tumor volume over days post-implantation of A431 human squamous tumor cells in immunocompromised mice where the group dosed with M1593 reduced growth of an established tumor.

FIG. 8 shows a plot of the percent target cell lysis (MDA-MB231 cells) by human PBMC versus MAb concentrations for the murine variable domain-human IgG1 (M1), murine variable domain-human IgG4 with alanine substitution at positions 234 and 235, M1593 as wild-type IgG1 produced in unmodified CHO, as M1593-LF produced in a CHO line selected for producing glycan with low fucose content, and M1593-DE with Kabat position substitutions at S239D and 1332E.

DESCRIPTION OF THE SEQUENCE LISTING

SEQ ID NO: Description Features or Origin 1 Human Tissue Factor ECD = 1-219 Mature Chain 2 Cynomolgous Monkey ECD only 1-220 Tissue Factor ECD 3 Mus musculus Tissue ECD = 1-221 Factor (P20352) 4 10H10 Heavy Chain (HC) Variable Region 5 10H10 Light Chain (LC) Variable Region 6 H-CDR1 of 10H10 7 H-CDR2 of 10H10 8 H-CDR3 of 10H10 9 L-CDR1 of 10H10 10 L-CDR2 of 10H10 11 L-CDR3 of 10H10 12 H15 IGHV5-a 13 H16 IGHV1-46 14 H17 IGHV1-3 15 H18 IGHV3-74 16 H19 IGHV1-69 17 H20 IGHV1-18 18 H21 IGHV1-f 19 H22 s1_IGHV5-a 20 H23 s1_IGHV1-69 21 H24 s1_IGHV1-f 22 L2 IGKV4-1_B3 23 L3 IGKV2D40_O1 24 L4 IGKV2D-28_A3 25 L5 IGKV2D-29_A2 26 L7 IGKV2-24_A23 27 H-CDR2 of H22, H23, Murine, Kabat -7 and H24 28 FR1 of H15 and H22 IGHV5-a 29 FR1 of H16, H17 and IGHV1-6, IGHV1- H20 3, IGHV1-18 30 FR1 of H18 IGHV3-74 31 FR1 of H19 and H23 IGHV1-69 32 FR1 of H21 and H24 33 FR2 of H15 and H22 IGHV5-a 34 FR2 of H16, H19, H20, FR2 of IGHV1-46, and H23_s1_IGHV1-69 IGHV1-69, IGHV1-18, and s1_IGHV1-69 35 FR2 of H17 IGHV1-3 36 FR2 of H18 IGHV3-74 37 FR2 of H21 and H24 IGHV1-f 38 FR3 of H15 IGHV5-a 39 FR3 of H16 IGHV1-46 40 FR3 of H17 IGHV1-3 41 FR3 of H18 IGHV3-74 42 FR3 of H19 IGHV1-69 43 FR3 of H20 IGHV1-18 44 FR3 of H21 IGHV1-f 45 FR3 of H22 s1_IGHV5-a 46 FR3 of H23 s1_IGHV1-69_(—) 47 FR3 of H24 s1_IGHV1-f 48 FR1 of L2 IGKV4-1_B3 49 FR1 of L3 IGKV2D40_O1 50 FR1 of L4 IGKV2D-28_A3 51 FR1 of L5 IGKV2D-29_A2 52 FR1 of L7 IGKV2-24_A23 53 FR2 of L2 IGKV4-1_B3 54 FR2 of L3 & L4 IGKV2D-28_A3 55 FR2 of L5 IGKV2D-29_A2 56 FR2 of L7 IGKV2-24_A23 57 FR3 of L2 IGKV4-1_B3 58 FR3 of L3, L4, and L5 IGKV2D40_O1, IGKV2D-28_A3, IGKV2D-29_A2 59 FR3 of L7 IGKV2-24_A23 60 FR4 HC IGHJ4 61 FR4 LC IGKJ2 62 H-CDR1 of H106 in M1602 63 H-CDR1 of H116 in M1587 64 H-CDR1 of H117 in M1590 65 H-CDR1 of H122 in M1591 66 H-CDR1 of H133 in M1612 67 H-CDR1 of H134 in M1597 68 H-CDR1 of H136 in M1613, and H185 of M1596 69 H-CDR1 of H136 in M1613 70 H-CDR1 of H139 in M1585 71 H-CDR1 of H158 in M1594 72 H-CDR1 of H160 in M1595 M1595 73 H-CDR1 of H164 in M1586 74 H-CDR1 of H165 in M1592 75 H-CDR1 of H168 in M1605 76 H-CDR1 of H171 in M1593 77 H-CDR1 of H173 in M1584 78 H-CDR1 of H179 in M1588 79 H-CDR1 of H181 in M1606 80 H-CDR1 of H187 in M1589 81 H-CDR1 of H189 in M1607 82 H-CDR1 of H177, H130, H105, and H128 83 H-CDR1 variants 84 H-CDR2 of H106 in M1602 85 H-CDR2 of H115 in M1610 86 H-CDR2 of H116 in M1587 87 H-CDR2 of H117 in M1590 88 H-CDR2 of H128 in M1611 89 H-CDR2 of H130 in M1599 90 H-CDR2 of H134 in M1597 91 H-CDR2 of H136 in M1613 92 H-CDR2 of H137 in M1598 93 H-CDR2 of H138 in M1604 94 H-CDR2 of H160 in M1595 95 H-CDR2 of H164 in M1586 96 H-CDR2 of H165 in M1592 97 H-CDR2 of H168 in M1605 98 H-CDR2 of H171 in M1593 99 H-CDR2 of H173 in M1584 100 H-CDR2 of H177 in M1583 101 H-CDR2 of H179 in M1588 102 H-CDR2 of H181 in M1606 103 H-CDR2 of H185 in M1596 104 H-CDR2 of H187 in M1589 105 H-CDR2 of H189 in M1607 106 H-CDR2 of H207 in M1608 107 H-CDR2 variants 108 L-CDR1 of L138 in both M1646 & M1638 109 L-CDR1 of L162 in both M1651 & M1643 110 L-CDR1 of L225 in both M1652 & M1644 111 L-CDR1 of L283 in both M1653 & M1645 112 L-CDR1 of L320 in both M1647 & M1639 113 L-CDR1 of L327 in both M1648 & M1640 114 L-CDR1 of L335 in both M1649 & M1641 115 L-CDR1 of L369 in both M1650 & M1642 116 L-CDR1 variants 117 L-CDR2 of L138 in both M1646 & M1638 118 L-CDR2 of L320 in both M1647 & M1639 119 L-CDR2 of L335 in both M1649 & M1641 120 L-CDR2 Variants 121 L-CDR3 of L162 in both M1651 & M1643 122 L-CDR3 of L225 in both M1652 & M1644 123 L-CDR3 of L283 in both M1653 & M1645 124 L-CDR3 of L320 in both M1647 & M1639 125 L-CDR3 of L327 in both M1648 & M1640 126 L-CDR3 of L335 in both M1649 & M1641 127 L-CDR3 of L369 in both M1650 & M1642 128 L-CDR3 Variants 129 H177 130 H173 131 H139 132 H164 133 H116 134 H179 135 H187 136 H117 137 H122 138 H165 139 H171 140 H158 141 H160 142 H185 143 H134 144 H137 145 H130 146 H105 147 H106 148 H138 149 H168 150 H181 151 H189 152 H207 153 H115 154 H128 155 H133 156 H136 157 L138 158 L320 159 L327 160 L335 161 L369 162 L162 163 L225 164 L283 165 M1593 full-length light chain 166 M1593 full-length heavy chain 167 M1593-DE full-length heavy chain

DETAILED DESCRIPTION OF THE INVENTION Abbreviations

TF=Tissue Factor, huTF=Human Tissue Factor, muTF=Murine Tissue Factor, cynoTF=Cynomolgus Tissue Factor, TF-FVIIa=Tissue Factor-Factor VIIa complex, TF/FVIIa=Tissue Factor-Factor VIIa complex, HC=Heavy chain, LC=Light chain, v-region=variable region, VH=Heavy chain variable region, VL=Light chain variable region, CCD=Charge-coupled device, CDR=Complementarity determining region, CHES=2-(N-cyclohexylamino)-ethanesulfonic acid, EDTA=Ethylenediaminetetraacetic acid, ECD=Extracellular domain, HEPES=N-(2-hydroxyethyl)-piperazine-N′-2-ethanesulfonic acid, HEK=Human embryonic kidney cells, MES=2-(N-morpholino)ethanesulfonic acid, PAR=Protease activated receptor, PBMC=peripheral blood mononuclear cells, PBS=Phosphate buffered saline, PDB=Protein Data Bank, PEG=Polyethylene glycol, SDS PAGE=Sodium dodecyl sulfate polyacrylamide gel electrophoresis, SEC=Size exclusion chromatography, MAb=Monoclonal antibody, FR=Framework in antibody, HFA=Human Framework adaption.

Definitions & Explanation of Terminology

As used herein, an “antibody” includes whole antibodies and any antigen binding fragment or a single chain thereof. Thus, the antibody includes any protein or peptide containing molecule that comprises at least a portion of an immunoglobulin molecule, such as but not limited to, at least one complementarity determining region (CDR) of a heavy or light chain or a ligand binding portion thereof, a heavy chain or light chain variable region, a heavy chain or light chain constant region, a framework (FR) region, or any portion thereof, or at least one portion of a binding protein, which can be incorporated into an antibody of the present invention. The term “antibody” is further intended to encompass antibodies, digestion fragments, specified portions and variants thereof, including antibody mimetics or comprising portions of antibodies that mimic the structure and/or function of an antibody or a specified fragment or portion thereof, including single chain and single domain antibodies and fragments thereof. Functional fragments include antigen-binding fragments to a preselected target. Examples of binding fragments encompassed within the term “antigen binding portion” of an antibody include (i) a Fab fragment, a monovalent fragment consisting of the VL, VH, CL and CH, domains; (ii) a F(ab′)2 fragment, a bivalent fragment comprising two Fab fragments linked by a disulfide bridge at the hinge region; (iii) a Fd fragment consisting of the VH and CH, domains; (iv) a Fv fragment consisting of the VL and VH domains of a single arm of an antibody, (v) a dAb fragment (Ward et al., (1989) Nature 341:544-546), which consists of a VH domain; and (vi) an isolated complementarity determining region (CDR). Furthermore, although the two domains of the Fv fragment, VL and VH, are coded for by separate genes, they can be joined, using recombinant methods, by a synthetic linker that enables them to be made as a single protein chain in which the VL and VH regions pair to form monovalent molecules (known as single chain Fv (scFv); see e.g., Bird et al. (1988) Science 242:423-426, and Huston et al. (1988) Proc. Natl. Acad. Sci. USA 85:5879-5883). Such single chain antibodies are also intended to be encompassed within the term “antigen-binding portion” of an antibody. These antibody fragments are obtained using conventional techniques known to those with skill in the art, and the fragments are screened for utility in the same manner as are intact antibodies. Conversely, libraries of scFv constructs can be used to screen for antigen binding capability and then, using conventional techniques, spliced to other DNA encoding human germline gene sequences. One example of such a library is the “HuCAL: Human Combinatorial Antibody Library” (Knappik, A. et al. J Mol Biol (2000) 296(1):57-86).

The term “CDR” refers to the complementarity determining region or hypervariable region amino acid residues of an antibody that participate in or are responsible for antigen-binding. The hypervariable region or CDRs of the human IgG subtype of antibody comprise amino acid residues from residues 24-34 (L-CDR1), 50-56 (L-CDR2) and 89-97 (L-CDR3) in the light chain variable domain and 31-35 (H-CDR1), 50-65 (H-CDR2) and 95-102 (H-CDR3) in the heavy chain variable domain as described by Kabat et al. (1991 Sequences of Proteins of Immunological Interest, 5th Ed. Public Health Service, National Institutes of Health, Bethesda, Md.) and/or those residues from a hypervariable loop (i.e., residues 26-32 (L1), 50-52 (L2) and 91-96 (L3) in the light chain variable domain and 26-32 (H1), 52-56 (H2), and 95-101 (H3) in the heavy chain variable domain as described by (Chothia and Lesk, 1987 J. Mol. Biol. 196: 901-917). Chothia and Lesk refer to structurally conserved hypervariable loops as “canonical structures”. Framework or FR1-4 residues are those variable domain residues other than and bracketing the hypervariable regions. The numbering system of Chothia and Lesk takes into account differences in the number of residues in a loop by showing the expansion at specified residues denoted by the small letter notations, e.g. 30a, 30b, 30c, etc. More recently, a universal numbering system has been developed and widely adopted, international ImMunoGeneTics information System® (IMGT) (LaFranc, et al. 2005. Nucl Acids Res. 33:D593-D597).

Herein, the CDRs are referred to in terms of both the amino acid sequence and the location within the light or heavy chain by sequential numbering. As the “location” of the CDRs within the structure of the immunoglobulin variable domain is conserved between species and present in structures called loops, by using numbering systems that align variable domain sequences according to structural features, CDR and framework residues and are readily identified. This information is used in grafting and replacement of CDR residues from immunoglobulins of one species into an acceptor framework from, typically, a human antibody.

The terms “Fc,” “Fc-containing protein” or “Fc-containing molecule” as used herein refer to a monomeric, dimeric or heterodimeric protein having at least an immunoglobulin CH2 and CH3 domain. The CH2 and CH3 domains can form at least a part of the dimeric region of the protein/molecule (e.g., antibody).

The term “epitope” means a protein determinant capable of specific binding to an antibody. Epitopes usually consist of chemically active surface groupings of molecules such as amino acids or sugar side chains and usually have specific three-dimensional structural characteristics, as well as specific charge characteristics. Conformational and nonconformational epitopes are distinguished in that the binding to the former but not the latter is lost in the presence of denaturing solvents.

As used herein, K_(D) refers to the dissociation constant, specifically, the antibody K_(D) for a predetermined antigen, and is a measure of affinity of the antibody for a specific target. High affinity antibodies have a K_(D) of 10⁻⁸ M or less, more preferably 10⁻⁹ M or less and even more preferably 10⁻¹⁰ M or less, for a predetermined antigen. The reciprocal of K_(D) is K_(A), the association constant. The term “k_(dis)” or “k₂,” or “k_(d)” as used herein, is intended to refer to the dissociation rate of a particular antibody-antigen interaction. The “K_(D)” is the ratio of the rate of dissociation (k₂), also called the “off-rate (k_(off))” to the rate of association rate (k₁) or “on-rate (k_(on)).” Thus, K_(D) equals k₂/k₁ or k_(off)%_(on) and is expressed as a molar concentration (M). It follows that the smaller the K_(D), the stronger the binding. Thus, a K_(D) of 10⁻⁶ M (or 1 microM) indicates weak binding compared to 10⁻⁹ M (or 1 nM).

The terms “monoclonal antibody” or “monoclonal antibody composition” as used herein refer to a preparation of antibody molecules of single molecular composition. A monoclonal antibody composition displays a single binding specificity and affinity for a particular epitope. The term also includes “recombinant antibody” and “recombinant monoclonal antibody” as all antibodies are prepared, expressed, created or isolated by recombinant means, such as (a) antibodies isolated from an animal or a hybridoma prepared by the fusion of antibody secreting animal cells and an fusion partner, (b) antibodies isolated from a host cell transformed to express the antibody, e.g., from a transfectoma, (c) antibodies isolated from a recombinant, combinatorial human or other species antibody library, and (d) antibodies prepared, expressed, created or isolated by any other means that involve splicing of immunoglobulin gene sequences to other DNA sequences. An “isolated antibody,” as used herein, is intended to refer to an antibody which is substantially free of other antibodies having different antigenic specificities. An isolated antibody that specifically binds to an epitope, isoform or variant of human TF may, however, have cross-reactivity to other related antigens, e.g., from other species (e.g., TF species homologs). Moreover, an isolated antibody may be substantially free of other cellular material and/or chemicals. In one embodiment of the invention, a combination of “isolated” monoclonal antibodies having different specificities are combined in a well defined composition.

As used herein, “specific binding,” “immunospecific binding” and “binds immunospecifically” refers to antibody binding to a predetermined antigen. Typically, the antibody binds with a dissociation constant (K_(D)) of 10⁻⁷ M or less, and binds to the predetermined antigen with a K_(D) that is at least twofold less than its K_(D) for binding to a non-specific antigen (e.g., BSA, casein, or any other specified polypeptide) other than the predetermined antigen. The phrases “an antibody recognizing an antigen” and “an antibody specific for an antigen” are used interchangeably herein with the term “an antibody which binds specifically to an antigen.” As used herein “highly specific” binding means that the relative K_(D) of the antibody for the specific target epitope is at least 10-fold less than the K_(D) for binding that antibody to other ligands.

As used herein, “isotype” refers to the antibody class (e.g., IgM or IgG) that is encoded by heavy chain constant region genes. Some antibody classes further encompass subclasses which are also encoded by the heavy chain constant regions and further decorated by oligosaccharides at specific residues within the constant region domains (e.g. IgG1, IgG2, IgG3 and IgG4) which further impart biological functions to the antibody. For example, in human antibody isotypes IgG1, IgG3 and to a lesser extent, IgG2 display effector functions as do murine IgG2a antibodies.

By “effector” functions or “effector positive” is meant that the antibody comprises domains distinct from the antigen specific binding domains capable of interacting with receptors or other blood components such as complement, leading to, for example, the recruitment of macrophages and events leading to destruction of cells bound by the antigen binding domains of the antibody. Antibodies have several effector functions mediated by binding of effector molecules. For example, binding of the C1 component of complement to antibodies activates the complement system. Activation of complement is important in the opsonisation and lysis of cell pathogens. The activation of complement stimulates the inflammatory response and may also be involved in autoimmune hypersensitivity. Further, antibodies bind to cells via the Fc region, with a Fc receptor site on the antibody Fc region binding to a Fc receptor (FcR) on a cell. There are a number of Fc receptors which are specific for different classes of antibody, including IgG (gamma receptors), IgE (eta receptors), IgA (alpha receptors) and IgM (mu receptors). Binding of antibody to Fc receptors on cell surfaces triggers a number of important and diverse biological responses including engulfment and destruction of antibody-coated particles, clearance of immune complexes, lysis of antibody-coated target cells by killer cells (called antibody-dependent cell-mediated cytotoxicity, or ADCC), release of inflammatory mediators, placental transfer and control of immunoglobulin production.

The terms “tissue factor protein”, “tissue factor” and “TF” are used to refer to a polypeptide having an amino acid sequence corresponding to a naturally occurring human tissue factor or a recombinant tissue factor as described below. Naturally occurring TF includes human species as well as other animal species such as rabbit, rat, porcine, non human primate, equine, murine, and ovine tissue factor (see, for example, Hartzell et al., (1989) Mol. Cell. Biol., 9:2567-2573; Andrews et al., (1991) Gene, 98:265-269; and Takayenik et al., (1991) Biochem. Biophys. Res. Comm., 181:1145-1150). The amino acid sequence of human tissue factor is given by the UniProt record P13726 (SEQ ID NO: 1), cynomolgous monkey (SEQ ID NO: 2), and murine by UniProt P20352 (SEQ ID NO: 3). The amino acid sequence of the other mammalian tissue factor proteins are generally known or obtainable through conventional techniques.

The antibodies of the invention are useful for administering to a human subject or for contacting human tissue where it is desired to block the functions of human TF expressed on a cell, tissue, or organ resulting from TF signaling and wherein it is also desired to not substantially alter the procoagulant functions of TF resulting from the formation of a TF:FVIIa complex. Such uses can be found in the treatment of tumors, in particular, primary or secondary solid tumors of the breast, prostate, lung, pancreas, and ovary.

The invention also encompasses nucleic acids encoding the antibody sequences of the invention which can be combined with those sequences known in the art to be useful in the construction and manufacture through recombinant means or transfer of the information for expression of the antibodies in a milieu where it is desired that they be formed, such in culture, in situ, and in vivo. The means for the operation of such nucleic acids with the intent of producing an antibody of the invention are well known to those skilled in the art.

The invention further provides for preparations such as pharmaceutically acceptable or stable preparations for administration and storage of an antibody of the invention in isolated form.

1. Composition of the Antibody

Properties

The present invention is based on the unexpected discovery that a non-coagulation blocking murine antibody which binds to human TF, known as 10H10 (Edgington, et al. U.S. Pat. No. 5,223,427) is capable of abrogating the signaling of TF in certain cells (Ahmed, et al. 2006, cited above, WO2007/056352A2). Therefore, an antibody of the invention is one that which retains the binding epitope of the murine antibody 10H10, which antibody does not compete with tissue factor for FVIIa binding and does not substantially block the procoagulant, amidolytic activity of the TF-VIIa complex and which does block TF-VIIa mediated signaling and downstream oncogenic effects such as cytokine IL-8 release. The antibody of the invention is adapted to human germline IgG genes as represented in the IMGT database and retains binding to human TF while not interfering with the ability of TF to initiate coagulation in the presence of calcium in human plasma.

An antibody that retains the binding epitope of murine antibody 10H10 can be assessed generally by assessing the ability of the antibody bind to TF and to compete with 10H10 for binding to human TF while at the same time, when present in a sample comprising TF in the presence of human plasma, will not substantially prolong the time required for the TF initiated coagulation of the plasma as compared to a like sample of human plasma in the absence of the antibody. In another sense, the epitope of the antibody can be physically mapped using techniques known in the art, including but not limited to deletion mutagenesis, substitution mutagenesis, limited proteolysis of TF bound by the antibody followed by peptide fragment identification, and co-crystallization and X-ray diffraction methods to map proximity of atomic structures of the primary structures of TF and the antibody binding domains thereby defining a three-dimensional association between the antibody and human TF (FIG. 1).

The epitope, thus, can be defined as non-overlapping with the FVIIa binding site (FIGS. 2 and 3). More specifically, the epitope bound by the antibody of the invention may contact one or more residues in the N-domain of TF (residues 1-104 of the mature chain as represented by SEQ ID NO: 1) not contacted by FVII, such as residues 65-70, and not contact residues K165 and K166 in the C-domain, which are important for substrate binding (Kirchofer et al. 2000 Thromb Haemostat 84: 1072-81) while not interfering with the ability of TF to initiate coagulation in the presence of calcium in human plasma.

In one embodiment the on-rate (k_(a) in 1/M·s) of the antibody is greater than 1×10⁻⁵. In another embodiment, the off-rate (k_(d) in 1/s) of the antibody for TF is less than 1.0×10⁻⁵ and the resulting K_(D) is less than 1×10⁻⁹ M (less than 1 nM). In a particular embodiment, the antibody is a human germline gene adapted antibody with a K_(D) less than 0.5×10⁻⁹ M. In one embodiment the antibody has binding domains selected from those of the heavy and light chain pairings as shown in Table 11 such as M1639, M1645, M1647, M1652, M1641, M1644, M1587, M1604, M1593, M1606, M1584, M1611, M1596, M1601, M1588, M1594, M1607, M1612, M1595, M1599, M1589, M1592, M1583, and M1610.

The antibody composition may be further characterized as comprising a sequence of amino acid residues in the binding domain selected from one or more of the amino acid sequences given by SEQ ID NO: 6-166.

Antibody Variants with Altered Fc Functions

As the use of therapeutic monoclonal antibodies produced by recombinant methods expands, features and properties of these complex compositions are being explored. While the immunospecific and antigen targeting features generally reside in the variable domains and subdomains such as the loop ends of the hypervariable regions also known as the CDRs, the complex interacts with other receptors and serum components afforded by the structures formed by the constant domains, such as the Fc portion of an IgG.

Antibodies and other Fc-containing proteins can be compared for functionality by several well-known in vitro assays. In particular, affinity for members of the FcγRI, FcγRII, and FcγRIII family of Fcγ receptors is of interest. These measurements could be made using recombinant soluble forms of the receptors or cell-associated forms of the receptors. In addition, affinity for FcRn, the receptor responsible for the prolonged circulating half-life of IgGs, can be measured, for example, by BIAcore using recombinant soluble FcRn. Cell-based functional assays, such as ADCC assays and CDC assays, provide insights into the likely functional consequences of particular variant structures. In one embodiment, the ADCC assay is configured to have NK cells be the primary effector cell, thereby reflecting the functional effects on the FcγRIIIA receptor. Phagocytosis assays may also be used to compare immune effector functions of different variants, as can assays that measure cellular responses, such as superoxide or inflammatory mediator release. In vivo models can be used as well, as, for example, in the case of using variants of anti-CD3 antibodies to measure T cell activation in mice, an activity that is dependent on Fc domains engaging specific ligands, such as Fcγ receptors.

2. Generation of Tissue Factor Signal-Blocking Antibodies

An antibody having the features and biologic activity of an antibody described in this application can include or be derived from any mammal, such as, but not limited to, a human, a mouse, a rabbit, a rat, a rodent, a primate, a goat, or any combination thereof and includes isolated human, primate, rodent, mammalian, chimeric, human- or primate-adapted antibodies, immunoglobulins, cleavage products and other specified portions and variants thereof. Monoclonal antibodies may be prepared by any method known in the art such as the hybridoma technique (Kohler and Milstein, 1975, Nature, 256:495-497) and related methods using immortalized fusion partners fused to B-cells. Antibodies for use in the invention may also be generated using single lymphocyte antibody methods by cloning and expressing immunoglobulin variable region cDNAs generated from single lymphocytes selected for the production of specific antibodies by for example the methods described by Babcook, J. et al., 1996, Proc. Natl. Acad. Sci. USA 93(15):7843-78481; WO92/02551; WO2004/051268 and International Patent Application number WO2004/106377.

The antibodies, including the target binding domains or subdomains, the constant domains, and the functional non-target binding domains such as the Fc-domain as described herein can be derived in several ways well known in the art. In one aspect, the sequences of naturally occurring antibody domains are conveniently obtained from published or on-line documents or databases, such as V-base (provided by the MRC Centre for Protein Engineering), the National Center for Biologics Information (NCBI Ig blast), or the ImMunoGeneTics (IMGT) database provided by the International Immunogenetics Information System®.

Human Antibodies

The invention further provides human immunoglobulins (or antibodies) which bind human TF. These antibodies can also be characterized as engineered or adapted. The immunoglobulins have variable region(s) substantially from a human germline immunoglobulin and include directed variations in residues known to participate in antigen recognition, e.g. the CDRs of Kabat or the hypervariable loops as structurally defined. The constant region(s), if present, are also substantially from a human immunoglobulin. The human antibodies exhibit K_(D) for TF of at least about 10⁻⁶ M (1 microM), about 10⁻⁷ M (100 nM), 10⁻⁹ M (1 nM), or less. To affect a change in affinity, e.g., improve affinity or reduce K_(D), of the human antibody for TF, substitutions in either the CDR residues or other residues may be made.

The source for production of human antibody which binds to TF is preferably the sequences provide herein as the variable regions comprising a sequence selected from SEQ ID NO: 129-163, a FR selected from SEQ ID NO: 28-61, and CDRs, where the CDRs are selected from one or more of SEQ ID NO: 6-11, 27, 62-128 identified as capable of binding human TF and cross-reacting with cynomolgous monkey TF using a repertoire of human derived Fab displayed on filamentous phage particles.

The substitution of any of non-human CDRs into any human variable domain FR may not allow the same spatial orientation provided by the conformation to the parent variable FR from which the CDRs originated. The heavy and light chain variable framework regions to be paired in the final MAb can be derived from the same or different human antibody sequences. The human antibody sequences can be the sequences of naturally occurring human antibodies, be derived from human germline immunoglobulin sequences, or can be consensus sequences of several human antibody and/or germline sequences.

Suitable human antibody sequences are identified by computer comparisons of the amino acid sequences of the mouse variable regions with the sequences of known human antibodies. The comparison is performed separately for heavy and light chains but the principles are similar for each.

With regard to the empirical method, it has been found to be particularly convenient to create a library of variant sequences that can be screened for the desired activity, binding affinity or specificity. One format for creation of such a library of variants is a phage display vector. Alternatively, variants can be generated using other methods for variegation of a nucleic acid sequence encoding the targeted residues within the variable domain.

Another method of determining whether further substitutions are required, and the selection of amino acid residues for substitution, can be accomplished using computer modeling. Computer hardware and software for producing three-dimensional images of immunoglobulin molecules are widely available. In general, molecular models are produced starting from solved structures for immunoglobulin chains or domains thereof. The chains to be modeled are compared for amino acid sequence similarity with chains or domains of solved three dimensional structures, and the chains or domains showing the greatest sequence similarity is/are selected as starting points for construction of the molecular model. The solved starting structures are modified to allow for differences between the actual amino acids in the immunoglobulin chains or domains being modeled, and those in the starting structure. The modified structures are then assembled into a composite immunoglobulin. Finally, the model is refined by energy minimization and by verifying that all atoms are within appropriate distances from one another and that bond lengths and angles are within chemically acceptable limits.

Because of the degeneracy of the code, a variety of nucleic acid sequences will encode each immunoglobulin amino acid sequence. The desired nucleic acid sequences can be produced by de novo solid-phase DNA synthesis or by PCR mutagenesis of an earlier prepared variant of the desired polynucleotide. All nucleic acids encoding the antibodies described in this application are expressly included in the invention.

The variable segments of human antibodies produced as described herein are typically linked to at least a portion of a human immunoglobulin constant region. The antibody will contain both light chain and heavy chain constant regions. The heavy chain constant region usually includes CH1, hinge, CH2, CH3, and, sometimes, CH4 domains.

The human antibodies may comprise any type of constant domains from any class of antibody, including IgM, IgG, IgD, IgA and IgE, and any subclass (isotype), including IgG1, IgG2, IgG3 and IgG4. When it is desired that the humanized antibody exhibit cytotoxic activity, the constant domain is usually a complement-fixing constant domain and the class is typically IgG₁. When such cytotoxic activity is not desirable, the constant domain may be of the IgG₂ class. The humanized antibody may comprise sequences from more than one class or isotype.

Nucleic acids encoding humanized light and heavy chain variable regions, optionally linked to constant regions, are inserted into expression vectors. The light and heavy chains can be cloned in the same or different expression vectors. The DNA segments encoding immunoglobulin chains are operably linked to control sequences in the expression vector(s) that ensure the expression of immunoglobulin polypeptides. Such control sequences include a signal sequence, a promoter, an enhancer, and a transcription termination sequence (see Queen et al., Proc. Natl. Acad. Sci. USA 86, 10029 (1989); WO 90/07861; Co et al., J. Immunol. 148, 1149 (1992), which are incorporated herein by reference in their entirety for all purposes).

The antibodies or Fc or components and domains thereof may also be obtained from selecting from libraries of such domains or components, e.g., a phage library. A phage library can be created by inserting a library of random oligonucleotides or a library of polynucleotides containing sequences of interest, such as from the B-cells of an immunized animal or human (Hoogenboom, et al. 2000, Immunol. Today 21(8) 371-8). Antibody phage libraries contain heavy (H) and light (L) chain variable region pairs in one phage allowing the expression of single-chain Fv fragments or Fab fragments (Hoogenboom, et al. 2000 supra). The diversity of a phagemid library can be manipulated to increase and/or alter the immunospecificities of the monoclonal antibodies of the library to produce and subsequently identify additional, desirable, human monoclonal antibodies. For example, the heavy (H) chain and light (L) chain immunoglobulin molecule encoding genes can be randomly mixed (shuffled) to create new HL pairs in an assembled immunoglobulin molecule. Additionally, either or both the H and L chain encoding genes can be mutagenized in a complementarity determining region (CDR) of the variable region of the immunoglobulin polypeptide, and subsequently screened for desirable affinity and neutralization capabilities. Antibody libraries also can be created synthetically by selecting one or more human FR sequences and introducing collections of CDR cassettes derived from human antibody repertoires or through designed variation (Kretzschmar and von Ruden 2000, Current Opinion in Biotechnology, 13:598-602). The positions of diversity are not limited to CDRs, but can also include the FR segments of the variable regions or may include other than antibody variable regions, such as peptides.

Other libraries of target binding or non-target binding components which may include other than antibody variable regions are ribosome display, yeast display, and bacterial displays. Ribosome display is a method of translating mRNAs into their cognate proteins while keeping the protein attached to the RNA. The nucleic acid coding sequence is recovered by RT-PCR (Mattheakis, L. C. et al. 1994. Proc. Natl. Acad. Sci. USA 91, 9022). Yeast display is based on the construction of fusion proteins of the membrane-associated alpha-agglutinin yeast adhesion receptor, aga1 and aga2, a part of the mating type system (Broder, et al. 1997. Nature Biotechnology, 15:553-7). Bacterial display is based on fusion of the target to exported bacterial proteins that associate with the cell membrane or cell wall (Chen and Georgiou 2002. Biotechnol Bioeng, 79:496-503).

The invention also provides for nucleic acids encoding the compositions of the invention as isolated polynucleotides or as portions of expression vectors including vectors compatible with prokaryotic, eukaryotic or filamentous phage expression, secretion and/or display of the compositions or directed mutagens thereof

3. Methods of Producing the Antibody of the Invention

Once an antibody molecule of the invention has been identified according to the structural and functional characteristics described herein, nucleic acid sequences encoding the desired portions of, or the entire antibody chains, can be cloned, copied, or chemically synthesized and can be isolated and used to express the antibody by routine methods. The antibody of the invention may be purified by any method known in the art for purification of an immunoglobulin molecule, for example, by chromatography (e.g., ion exchange, affinity, and sizing column chromatography), centrifugation, differential solubility, or by any other standard technique for the purification of proteins. In addition, the antibodies of the present invention or fragments thereof can be fused to heterologous polypeptide sequences described herein or otherwise known in the art, to facilitate purification.

Host Cell Selection or Host Cell Engineering

As described herein, the host cell chosen for expression of the recombinant Fc-containing protein or monoclonal antibody is an important contributor to the final composition, including, without limitation, the variation in composition of the oligosaccharide moieties decorating the protein in the immunoglobulin CH2 domain. Thus, one aspect of the invention involves the selection of appropriate host cells for use and/or development of a production cell expressing the desired therapeutic protein.

Further, the host cell may be of mammalian origin or may be selected from COS-1, COS-7, HEK293, BHK21, CHO, BSC-1, Hep G2, 653, SP2/0, 293, HeLa, myeloma, lymphoma, yeast, insect or plant cells, or any derivative, immortalized or transformed cell thereof.

Alternatively, the host cell may be selected from a species or organism incapable of glycosylating polypeptides, e.g. a prokaryotic cell or organism, such as and of the natural or engineered E. coli spp, Klebsiella spp., or Pseudomonas spp.

4. Methods of Using an Anti-TF Antibody

The compositions (antibody, antibody variants, or fragments) generated by any of the above described methods may be used to diagnose, treat, detect, or modulate human disease or specific pathologies in cells, tissues, organs, fluid, or, generally, a host. As taught herein, modification of the Fc portion of an antibody, Fc-fusion protein, or Fc fragment to provide a more specifically suited range of effector functions after target binding but where in the antibody retains the original targeting properties will generate variants of the antibody for specific applications and therapeutic indications.

The diseases or pathologies that may be amenable to treatment using a composition provided by the invention include, but are not limited to: cancer; including primary solid tumors and metastases; carcinomas, adenocarcinomas, melanomas, liquid tumors such as lymphomas, leukemias and myelomas and invasive masses formed as the cancer progresses; soft tissue cancers; sarcomas, osteosarcoma, thymoma, lymphosarcoma, fibrosarcoma, leiomyosarcoma, lipomas, glioblastoma, astrosarcoma, cancer of the prostate, breast, ovary, stomach, pancreas, larynx, esophagus, testes, liver, parotid, biliary tract, colon, rectum, cervix, uterus, endometrium, thyroid, lung, kidney, or bladder.

In so far as the antibody of the invention reduces the pro-oncogenic milieu in a tissue by blocking the ability of TF to participate in the downstream release of cytokines such as the inflammatory cytokine, IL-8, the antibody of the invention can be used prophylactically or in conjunction with other treatments directed to suppressing tumor proliferation and angiogenesis. Most age-related cancers derive from the epithelial cells of renewable tissues. An important element of epithelial tissues is the stroma, the sub-epithelial layer composed of extracellular matrix and several cell types including fibroblasts, macrophages, and endothelial cells. In cancerous tumors the stroma is critical for tumor growth and progression and TF can be expressed on stromal cells as well as the cancerous epithelial cells. Therefore, the presence of the downstream factors resulting from TF:VIIa signaling in stroma may create a pro-oncogenic tissue environment that synergizes with oncogenic mutations to drive the formation of neoplastic tissue.

Similarly, when TF is expressed in adipose tissue it can modify the function of the tissue in conditions such as obesity, metabolic syndrome, and diabetes. The antibody of the invention can be useful in treating these conditions by blocking TF:VIIa signaling. Some of the factors produced downstream of TF:FVIIa signaling, including IL-8 and IL-6, are powerful mediators of inflammation. Additional uses of the antibody of the invention therefore include treatment of inflammatory conditions such as, but not limited to, rheumatoid arthritis, inflammatory bowel disease, and asthma.

As the antibody of the invention inhibits TF:VIIa signaling and reduces downstream effects promoting angiogenesis, the antibodies of the invention can be useful in treating other diseases, disorders, and/or conditions, in addition to cancers, which involve angiogenesis. These diseases, disorders, and/or conditions include, but are not limited to: benign tumors, for example hemangiomas, acoustic neuromas, neurofibromas, trachomas, and pyogenic granulomas; artheroscleric plaques; ocular angiogenic diseases, for example, diabetic retinopathy, retinopathy of prematurity, macular degeneration, corneal graft rejection, neovascular glaucoma, retrolental fibroplasia, rubeosis, retinoblastoma, uveitis and Pterygia (abnormal blood vessel growth) of the eye; rheumatoid arthritis; psoriasis; delayed wound healing; endometriosis; vasculogenesis; granulations; hypertrophic scars (keloids); nonunion fractures; scleroderma; trachoma; vascular adhesions; myocardial angiogenesis; coronary collaterals; cerebral collaterals; arteriovenous malformations; ischemic limb angiogenesis; Osler-Webber Syndrome; plaque neovascularization; telangiectasia; hemophiliac joints; angiofibroma; fibromuscular dysplasia; wound granulation; Crohn's disease; and atherosclerosis.

In so far as the antibody of the invention inhibits TF:VIIa signaling, the antibody can be used to treat and/or diagnose hyperproliferative diseases, disorders, and/or conditions, including but not limited to neoplasms. The antibody can inhibit proliferation of the disorder through direct or indirect interactions. Examples of hyperproliferative diseases, disorders, and/or conditions that can be treated, and/or diagnosed by the antibodies of the invention, include, hyperproliferative diseases, disorders, and/or conditions include, but are not limited to, hypergammaglobulinemia, lymphoproliferative diseases, disorders such as Castleman's disease, and/or conditions, paraproteinemias, purpura, sarcoidosis, Sezary Syndrome, Waldenstron's Macroglobulinemia, Gaucher's Disease, histiocytosis, and any other hyperproliferative disease in an organ, tissue or fluid body compartment.

Additional ways in which the antibodies of the present invention can be used therapeutically include, but are not limited to, directed cytotoxicity of the antibody, e.g., as mediated by complement (CDC) or by effector cells (ADCC), or indirect cytotoxicity of the antibody, e.g., as immunoconjugates.

While having described the invention in general terms, the embodiments of the invention will be further disclosed in the following examples that should not be construed as limiting the scope of the claims. In the experimental descriptions, certain reagents and procedures were used to produce proteins or an antibody or a specified fragment. Analytical methods routinely used to characterize the antibody are described below.

Materials and Methods

Protein and Antibody Standards

The recombinant extracellular domain (ECD) of human TF was constructed in two forms: for ELISA and Biacore-based direct binding assays, amino acid 1-219 of the mature chain of TF (SEQ ID NO: 1) was expressed in a mammalian system with a C-terminal His6-tag peptide; for co-crystallography studies, amino acid 5-213 of SEQ ID NO: 1 was expressed with a C-terminal His6-tag peptide in a bacterial system. Human_(TF1-219) was biotinylated using NHS-ester chemistry targeting amine residues on the protein. For coagulation assays, Innovin® (Dade Behring Inc. cat #B4212), a lyophilized recombinant human tissue factor combined with phospholipids, calcium, buffers and stabilizers for diagnostic use was used.

Cynomolgous monkey (cyno) TF-ECD (SEQ ID NO: 2) was cloned using PCR from cDNA isolated form cynomolgous testes tissue obtained from BioChain Institute (Hayward, Calif.).

Several antibodies were used as reference antibodies: i) 10H10 cloned from the original hybridoma TF9.10H10-3.2.2 (U.S. Pat. No. 7,223,427) ii) a 10H10 mouse-human chimera, comprising SEQ ID NO: 4 and SEQ ID NO: 5 with human IgG1/Kappa constant regions, designated M1 iii) M59, a human FR adapted antibody comprising the six CDRs of 10H10 and serving as the parent antibody for affinity maturation, comprising SEQ ID NO:19 and SEQ ID NO:23 with human IgG1 and human Kappa constant region; iv) murine anti-human tissue factor antibody TF8-5G9 (U.S. Pat. No. 7,223,427); v) a humanized from of the antibody 5G9, known as CNTO 860, as a human IgG1/Kappa (U.S. Pat. No. 7,605,235); and vi) an isotype control (human IgG1/kappa) antibody binding to an irrelevant antigen (RSV) called B37.

Antibody Expression and Purification

Routine procedures were used to express and purify the disclosed antibodies. For primary screening, DNA encoding these molecules were transiently expressed in 96-well plates in HEK 293E cells and the supernatants were tested for activity (binding) 96 hours following transfection. Hits were identified and chosen for pilot-scale expression and purification. Pilot-scale expression was done transiently in HEK 293F cells or CHO—S at a volume of 750 ml. The harvested supernatants were purified via Protein A chromatography and the purified proteins were assessed for their affinity and functional activity. In addition, the purified proteins were subjected to biophysical characterization by SDS-PAGE, SE-HPLC, and cross-interaction chromatography (CIC). Theoretical isoelectric points (pI) were calculated for each variant as well. From the pilot scale characterizations, a set of final lead candidates was transfected in WAVE bioreactors and purified via Protein A chromatography.

Fab Production and Monoclonal Fab ELISA

Glycerol stocks from phage panning rounds were miniprepped and the pIX gene was excised by NheI/SpeI digestion. After religation, the DNA was transformed into TG-1 cells and grown on LB/Agar plates overnight. The next day, colonies were picked, grown overnight, and the cultures used for (i) colony PCR and sequencing of the V-regions, and (ii) induction of Fab production. For Fab production, the overnight culture was diluted 10-100 fold in new media and grown for 5-6 hours at 37 degrees C. Fab production was induced by the addition of fresh media containing IPTG and the cultures were grown overnight at 30 degrees C. The following day, the cultures were spun down and the supernatants, containing the soluble Fab proteins, were used for Fab ELISA.

For Fab ELISA, Fabs were captured onto plates by a polyclonal anti-Fd(CH1) antibody. After appropriate washing and blocking, biotinylated hTF was added at 0.2 nM concentration. This concentration enables ranking of the Fab variants, defined as percent binding of the parent, in which the parent Fab, present as a control in all plates, is defined as 100% binding. The biotinylated hTF was detected by HRP-conjugated streptavidin and chemiluminescence read in a plate reader.

TF-ECD Binding Mab-Based ELISA

A solution Phase direct TF binding ELISA using chemiluminescent detection was used to rank the top binders from human framework adaptation library. The 96 well black maxisorp plates were coated with 100 uL of 4 ug/ml Goat anti human IgG FC diluted in carbonate-bicarbonate buffer, pH 9.4 at 4° C. overnight and then washed thrice with wash buffer (PBS with 0.05% Tween-20 solution) and blocked with 300 μl 1% BSA/10 mM PBS solution for 1 hour followed by a washing as before. Samples or standards were diluted to 50 ng/ml in Assay Buffer (1% BSA in PBS+05% Tween) and 100 ul was added to the assay plate at room temperature for 1 hour with shaking. The plates were washed thrice and 100 ul per well of human or cynomologus TF-ECD with His Tag was added at 100 ng/ml diluted in Assay Buffer and incubate for 2 hours at room temperature. After washing, 100 ul per well of Qiagen peroxidase conjugated penta-his at 1:2000 dilution in assay buffer was added and incubated 1 hour at room temperature with shaking. The BM ChemiLum Substrate (BM Chemilum, POD, Roche) was made freshly at 1:100 dilution into Buffer and 100 ul added to the plates after a final wash. After 10 minutes the plates are read on Perkin Elmer Envision Reader, BM ChemiLum program.

MDA-MB-231 Whole Cell Binding of Anti-Tissue Factor mAbs by FACS

This assay is used to detect the direct binding of antibody to endogenouse human TF expressed in breast cancer cells. Prepare four point titrations of the test mAbs in FACS buffer (1% FBS in PBS) in duplicate. Start a titration at 1,000 ng/ml with 1:4 dilutions. M1, the parent molecule, is used as positive control while B37, anti-RSV mAb, is used as negative/isotype control. Unstained cells and secondary antibody, Cy-5 conjugated Goat anti-Human IgG Fc antibody in FACS buffer 1:200, is used as controls and prepared immediately before use.

Using standard tissue culture technique, rinse adherent MDA-MB-231 cells in culture flask with once with PBS (w/o Ca+2/Mg+2). Lift cells with Versene and count the cells and seed 200,000 cells per well in a polystyrene V-bottom plate. FACS Analysis Protocol: Tissue Factor Binding. Pellet the cells in a Allegra X-15R centrifuge at 450×g for 3 minutes at 4° C., resuspend in FACS Buffer (2% FBS in PBS) and plate 200,000 cells per well in 200 uL. Pellet cells at 450×g for 3 minutes at 4° C. Discard supernatants and add 100 uL/well test or control mAbs to designated wells and incubate on ice or at 4° C. for 1 hour (+/−10 minutes). Pellet cells at 450×g for 3 minutes at 4° C. Discard supernatants and wash cells once in FACS buffer. Resuspend cells in 200 uL/well FACS buffer and pellet cells at 450×g for 3 minutes at 4° C. Discard supernatants and add 100 uL/well secondary antibody to designated wells (triterate), and incubate on ice for 1 hour (+/−10 minutes). Pellet cells at 450×g for 3 minutes at 4° C. Discard supernatants and wash cells 2 times in FACS buffer before resuspending the cells in 200 uL/well FACS Buffer (triterate). Pellet cells at 450×g for 3 minutes at 4° C. Discard supernatant and resuspend cells in 100 uL/well CytoFix Buffer. Analyze reactions by flow cytometry (BD FACSArray). The FlowJo Software is used for FACS data analysis by gating the main population of cells in the unstained control well and applying the gate to the whole data set. The data is exported as a table of the geometric mean fluorescence intensity (MFI) in the red channel for the applied gate.

Thermafluor Assay

Thermofluor technology is a kinetic measurement of the unfolding of a molecule as it is heated. As the molecule is heated, a dye (ANS) is able to bind to the molecule as it unfolds. The dye will fluoresce as it binds to the molecule, and this fluorescence is measured over time. In this assay, the unfolding of the antibodies was measured from 37-95° C., and detected every 0.5° C. The Tms of the parent molecules in both murine and chimera form (10H10, M1, 5G9 and CNTO860) were also measured, along with 2 mAbs with known Tms to be used as assay controls (Emmp 4A5, and Emmp 5F6).

This assay was used to predict thermal stability of the human framework adaptation library variants. Dilute purified antibodies to 0.5 mg/mL in PBS and add 2 ul sample to each well to total 1 ug sample per well. Each sample is added in duplicate. Stock ANS is at 500 mM in DMSO. Dilute stock ANS 1:12 into DMSO (to 40 mM); Make Dye/Tween solution by combining 20 ul of the 40 mM ANS solution, 2.8 ul 10% Tween and 1.98 mL PBS; add 2 uL Dye/Tween solution and 2 ul oil. Centrifuge plates (2 min at 450 rpm). Thermofluor Settings Shutter set to manual, Ramp Temperature 0.5 C/sec., Continuous Ramp, Temperature Ramp: 50-95° C. Select hold 15 s at high T., Exposure time 10 s/1 rep., Gain normal=2, Select “Single SC Image/plate”.

Cross Interaction Chromatography (CID)

To determine the interaction of the various antibodies with other human antibodies, chromatography experiments were performed using a column coupled with human IgG (Sigma Aldrich). Briefly, 50 mgs of human IgG were coupled to a 1 ml NHS-Sepharose column (GE Healthcare) following the manufacturer's instructions. Uncoupled IgG was removed by washing with 0.1M Tris, pH8, 0.5M NaCl and unreacted NHS groups were blocked with the same buffer. The coupling efficiency was determined by measuring the protein concentration remaining in the unreacted coupling buffer and washes using Pierce's Coomassie Plus Assay Kit (Thermo Pierce) and subtracting from the amount of protein before immobilization. A control column was also prepared using the same protocol only no protein was added to the resin.

The control column was run first on a Dionex UltiMate 3000 HPLC after being equilibrated with PBS, pH7 at a flow rate of 0.1 ml/min. 201 of the stock protein solution was injected first to ensure non-specific binding sites were blocked followed by 201 of 10% acetone to check the integrity of the column.

Samples to be analyzed were diluted to 0.1 mg/ml in PBS, pH7. 20 microL of each sample was injected onto each column and allowed to run at 0.1 ml/min for 30 min. Retention times were recorded and the retention factor (k′) was calculated for each variant.

The calculation of k′ is the difference in the retention time on a protein derivatized column (IgG coupled column), t_(R), and the retention time on a column with no protein coupled to it, to. The calculation also takes into account the retention time of acetone on both columns to standardize the column. Acceptable values for k′ are less than 0.3.

Solubility

To determine the solubility of the various antibodies at room temperature, concentration experiments were performed using centrifugal filter devices. Briefly, antibody preparations in PBS were added to Vivaspin-15 (15 ml) centrifugal filter devices (30,000 MWCO, Sartorius, Goettingen, Germany) at room temperature. The filters were spun at 3000×g for 20 minute intervals in a Beckman Allegra X15-R centrifuge using a swinging bucket rotor. Once the volumes were reduced to about 2 ml, the supernatant was transferred to a Vivaspin-4 (4 ml) filter device (30,000 MWCO) and centrifuged at 4,000×g for 20 min intervals. Once the volume was reduced to 5001, the sample was transferred to a Vivaspin-500 filter device and centrifuged at 15,000×g in an Eppendorf 5424 centrifuge for 15 minutes. This was repeated until the protein concentration reached 100 mg/ml or more. The protein concentration was determined by absorbance at 280 nm and 310 nm on a BioTek SynergyHT™ spectrophotometer with appropriate dilution. At this point, centrifugation was stopped and the sample kept at room temperature overnight to reach equilibrium. The next morning, the sample was checked for signs of precipitation. If the concentration was greater than 100 mg/ml, the process was stopped.

Factor VIIA-Induced IL-8 Inhibition Assay

This assay was used to test whether or not the TF-binding antibodies neutralize FVIIa-induced IL-8 release from human cells expressing TF. Human breast adenocarcinoma cells (MDA-MB-231) (ATCC: HTB-26), adapted to grow in DMEM and 10% FBS (Gibco: cat #11995 and cat #16140), were plated in 96-well cell culture plates (Nunc: cat #167008) at a density of 20000 cells per well (100,000 cells/mL) using standard cell culture techniques. The cells where allowed to recover for two days before antibody treatment starting at 2 ug/mL and undergoing either a 1:2 or 1:4 serial dilution in DMEM without FBS. The antibody was added one hour before treatment with human FVIIa (Innovative Research: cat #IHFVIIa, lot: 2824) at a final concentration of 50 nM in DMEM without FBS. The cells were placed in the incubator for 24 hours. After treatment, the supernatant were collected and the quantity of IL-8 was detected by ELISA according to manufactures protocol (R&D Systems: cat #D8000C). Briefly, the optical density (OD) of each treatment sample was read at 450 nm and 540 nm. The reading at 540 nm was used to correct for optical imperfection in the assay plate while the corrected reading at 450 nm (OD 450 minus OD 540) was used to calculate the IL-8 content in the treatment samples using an IL-8 Standard Curve prepared according to manufactures protocol. Wells with cells not receiving antibody and FVIIa treatment were used to define the endogenous IL-8 level while wells with cells only receiving FVIIa was used to define the “no inhibition” IL-8 level, thereby defining the minimum and maximum IL-8 levels, respectively. The MAb titration treatment samples where normalized to the maximum and minimum IL-8 levels as defined above and expressed as percent inhibition. The normalized data were either represented in bar graphs or fitted to a four-parameter logistic curve fit to extract EC₅₀ values for each MAb.

Coagulation Assay

This assay was used to determine whether or not the anti-human TF antibodies block coagulation in vitro using human plasma in the presence of calcium and added recombinant human TF preparation (Innovin, Dade Behring Inc). Anti-human TF antibodies are diluted to 2 mg/ml antibody in HB SS (Gibco, cat #14175). Pooled human plasma with Na Citrate (George King Biomedical, Novi, Mich.) is spun down at 1000 rpm for 5 min and clear plasma is transferred to a new tube. In each well of a clear 96 well assay plate (NUNC, cat #439454), 25 ul of the diluted antibody is added to 100 ul of the human plasma. The reaction is initiated by adding 125 μl of Innovin (Dade Behring Inc., cat #B4212) diluted 1:500 into HBSS with 22 mM CaCl₂ to each well containing plasma with or with antibody. The coagulation reaction is kinetically monitored at OD 405, immediately following reaction initiation and for 30 min at 37° C. using a SpectraMax M2e reader (Molecular Devices, Sunnyvale, Calif.). T½ Max is determined for each antibody using Softmax Pro Software as the time in seconds it takes to reach 50% of the maximum optical density. The time in seconds for samples was normalized to a reference on each plate, however, statistically there was no difference between samples listing 150 sec and 200 sec which was the average time for samples without antibody, for 10H10, and all of the 10H10 derived and human adapted variants.

EXAMPLE 1 Sequencing of 10H10

The murine antibody known as 10H10 generated at The Scripps Research Institute in La Jolla, Calif. (U.S. Pat. No. 5,223,427, Morrisey et al. 1988 Thromb Res. 52(3): 247-261) is produced by the hybridoma TF9.10H10-3.2.2. The sequences of the antibody from the 10H10 hybridoma clone, had not been previously reported.

The sequences were identified using the 5′RACE method (Focus 25 (2):25-27, 2003; Maruyama 1994 Gene 138, 171-174) where the two antibody chains, VH and VL, were amplified using 5′ GeneRacer™ (InVitrogen), primer and 3′ consensus primer complementary to a sequence within the mouse IgG1 constant region and mouse Kappa constant region, respectively. Nested PCR amplification using 5′GeneRacer Nested primer and a 3′ consensus primer was used to generate VL products more suitable for sequence analyses.

At least 16 clones were selected to identify the variable region of each chain. Primers were used to sequence through the unknown region of the inserts. The raw sequence data was downloaded from the ABI DNA Sequencer to Vector NTI (Invitrogen Informax) for sequence analysis. One functional VH and one functional VL were identified. Both VH and VL genes were further analyzed to find their native signal sequences, FR, CDR, and J-segments.

The 10H10 FRs and CDRs are numbered sequentially, and segmented following Kabat's definition (Kabat et al., 5th edit. Public Health Service, NIH, Washington, D.C., 1991), except in the region corresponding to the CDR-1 of VH. For this region a combination of Kabat and Chothia definition was used (Raghunathan, G., US2009/0118127 A1; Chothia and Lesk, J Mol Biol 196(4): 901-17, 1987).

TABLE 1 10H10 Sequence of the Variable Regions and its Sequence Structures Protein Name Polypeptide Sequence Subdomains 10H10 Heavy Chain QVHLQQSGAELMKPGASVKISCKAS FR1 = 1 to 25 Variable Region GYTFITYWIE CDR1 = 26 to 35 (SEQ ID NO: 6) (SEQ ID NO: 4) WVKQRPGHGLEWIG FR2 = 36 to 49 DILPGSGSTNYNENFKG CDR2 = 50 to 66 (SEQ ID NO: 7) KATFTADSSSNTAYMQLSSLTSEDSAVYYCAR FR3 = 67 to 98 SGYYGNSGFAY CDR3 = 99 to 109 (SEQ ID NO: 8) WGQGTLVTVSA FR4(JH3) = 110 to 120 10H10 Light Chain DIVMTQSPSSLTVTAGEKVTMSC FR 1 = 1 to 23 Variable Region KSSQSLLSSGNQKNYLT CDR1 = 24 to 40 (SEQ ID NO: 9) (SEQ ID NO: 5) WYQQIPGQPPKLLIY FR2 = 41 to 55 WASTRES CDR2 = 56 to 62 (SEQ ID NO: 10) GVPDRFTGSGSGTDFTLTINSVQAEDLAVYYC FR3 = 63 to 94 QNDYTYPLT CDR3 = 95 to 103 (SEQ ID NO: 11) FGAGTKLELK FR4(K5) = 104 to 113

The cloned V regions were engineered with human IgG1/Kappa constant regions and cloned into mammalian expression vectors for recombinant expression in HEK293 or CHO cell lines creating a mouse-human chimeric antibody designated M1, which was used in assay development as a reference antibody. The HC V-region was also engineered with human IgG1 CH1 domain only and a C-terminal hexahistidine for the purposes of producing a 10H10Fab used in crystal structure analysis.

EXAMPLE 2 Epitope Mapping of a Non-Anticoagulant Tissue Factor Antibody

Epitope mapping for 10H10 was performed by crystal structure determination of a complex between human TF ECD and the corresponding Fab fragment. The His-tagged human TF ECD (residues 5-213 of SEQ ID NO: 1) was expressed in Escherichia coli and purified by affinity and ion exchange chromatography using a HisTrap HP column (GE Healthcare) and a Q HP column (GE Healthcare), respectively. The His-tagged chimeric versions (mouse V regions, human constant domains) of 10H10 Fab was expressed in HEK cells and purified using affinity (a TALON column, GE Healthcare) and size exclusion (a HiLoad Superdex 200 column, GE Healthcare) chromatography.

The complex was prepared by mixing the Fab with human TF ECD at the molar ratio 1:1.2 (excess TF). The mixture was incubated for 20 min at room temperature and loaded on a Superdex 200 column (GE Healthcare) equilibrated with 20 mM HEPES, pH 7.5, and 0.1 M NaCl. Fractions corresponding to the main peak were pooled, concentrated to 10 mg/mL, and used for crystallization. The complex was crystallized by the vapor-diffusion method at 20° C. The 10H10:TF complex was crystallized from solution containing 18% PEG 8000 in 0.1 M CHES, pH 9.5. For X-ray data collection, one crystal of the complex was soaked for a few seconds in the mother liquor supplemented with 20% glycerol, and flash frozen in the stream of nitrogen at 100 K. X-ray diffraction intensities were measured using a Rigaku MicroMax™-007HF microfocus X-ray generator equipped with a Saturn 944 CCD detector and an X-stream™ 2000 cryo-cooling system (Rigaku). The structure was determined by molecular replacement using the CCP4 suite of programs for macromolecular crystallography (Collaborative Computational Project, Number 4. 1994. Acta Cryst. D50, 760-763).

The TF ECD consists of two topologically identical domains with the immunoglobulin fold. The N-terminal domain spans residues 1-103, and the C-terminal domain spans residues 104-210 (of the ECD, SEQ ID NO: 1). The 10H10 epitope was found to be centered on residues K149-D150 of the ECD, which reaches a deep pocket between the variable domains of the heavy and light chains of 10H10. The interface between 10H10 and TF is extensive and involves all six CDR loops (FIG. 1).

Notable findings are that the TF epitope of 10H10 does not overlap with the FVII and FX binding sites (FIGS. 2 and 3). Also, the epitopes of 10H10 and 5G9 (another murine human-TF binding antibody with ability to block coagulation and which epitope was previously published, Huang et al. 1998 J Mol Biol 275:873-94) do partially overlap explaining the competitive binding between these two antibodies to human TF (FIGS. 2 and 3).

Human TF ECD:10H10 Interface

10H10 binds TF at the interface between the N- and C-terminal domains of the ECD. The convex surface of TF fits to the concave CDR surface of the antibody. The total area buried upon complex formation is over 1,100 Å2 on each of the interacting molecules. All six CDRs are involved in direct contacts with TF (contacts defined as a 4-Å interatomic distance). In total, there are 24 epitope residues and 25 paratope residues. CDRs L1, H1 and H3 form the majority of contacts. Residues forming the epitope and the paratope of the 10H10:TF complex are shown schematically in FIG. 1.

The 10H10 epitope includes two segments from the N-domain and three segments from the C-domain of TF ECD. The two segments from the N-domain interact with the antibody: residues 65-70 interacts with H-CDR1 and H-CDR3 and residue 104 interacting with H-CDR1. The three segments in the C-domain interact with the antibody: residues 195 and 197 interact with H-CDR1 and H-CDR2, residues 171-174 interact with L-CDR1 and L-CDR3, and residues 129-150 interact with L-CDR1, L-CDR3, H-CDR1 and H-CDR3; TF residues K149-D150 are in the center of the epitope; reaching a deep pocket formed between the VL and VH domains where their primary partners are D97 of the LC variable region (SEQ ID NO:5) and W33 of the HC variable region (SEQ ID NO: 4) of 10H10, respectively.

B. Antibody Specificity

The amino acid sequences of human, cynomolgus (cyno) monkey (SEQ ID NO: 2) and mouse TF ECD (SEQ ID NO: 3) are aligned in FIG. 2. There is high similarity between the sequences of human and cynomolgus TF ECD, and the two are only one residue different in the 10H10 contact residues: position 197 of SEQ ID NO:1, which is R (Arg) in the cyno sequence. As the T197 in the human sequence is contacted by a single H-CDR2 residue, the high level of cross-reactivity seen for the present set of 10H10 derived antibodies is explainable.

By aligning the human and mouse TF sequences, the epitope residues determining the species specificity of 10H10 were evident as significant amino acid differences occur in epitope residues: among the 24 residues 10H10 contacts in human TF, the human and mouse sequences differ at positions 68, 69, 70, and 104; in the N-domain and positions 136, 142, 145 and 197 in the C-domain of SEQ ID NO: 1 versus SEQ ID NO: 3. The differences are consistent with the diminished binding affinity of 10H10 for mouse TF.

FIG. 2 also indicates the interaction sites on human TF for FVII and FX based on a theoretical 3D model (FIG. 3) that describes their association into a ternary complex (Norledge et al., Proteins 53:640-648, 2003). Antibody 5G9 binds TF at an epitope that partially overlaps with the FX binding site. Therefore 5G9 competes with FX and this causes blockage of the coagulation cascade. 10H10 differs from 5G9 in that it does not block coagulation while it effectively shuts off the signaling via TF-associated PARs. Based on the model of the ternary TF/FVII/FX complex, it was expected that the 10H10 epitope would be on the free surface of TF and centered around residues K149-D150. Binding of 10H10 mapped by mutagenesis and peptide epitope mapping provided early evidence that this was the case.

The present crystal structure of the complex between TF ECD and 10H10 Fab provides a spatial mapping of the manner in which the antibody can bind TF without preventing FVII and FX interaction either with TF or each other. The 10H10 epitope as revealed by the structure covers the free surface of TF as it theoretically exists in the ternary complex. Further, the 10H10 epitope partially overlaps that of the coagulation blocking MAb, 5G9, epitope (Huang 1998 supra), the common residues being K149 and N171. Neither 10H10 or 5G9 block FVII binding to TF. The epitopes of 10H10 and FX are also non-overlapping, but a steric clash occurs between the constant domain of the Fab and the protease (globular) domain of FX in the current model. It should be noted however that the orientation of FX may in fact differ from the model and that the association between FX and TF may allow some flexibility in the protease domain. There is also a considerable flexibility in the elbow angle between the variable and constant domains of the Fab that may allow to avoid the clash upon 10H10 binding to the ternary complex.

EXAMPLE 3 Adapting the Binding Domains for Use in Humans

Efficacy of a therapeutic protein can be limited by unwanted immune reactions. Non-human monoclonal antibodies can have substantial stretches of linear amino acid sequences and local structural conformations that can elicit immune response in humans. The transfer of the residues responsible for immunospecifity of target binding of a non-human MAb to a human antibody scaffold more often than not results in a substantial loss of binding affinity for the target antigen. Hence, it is highly valuable to use sound design principles for creating antibody molecules that elicit minimal immunogenic reactions while retaining the binding and biophysical profiles of the parent non-human molecule when injected into humans.

As previously described in US20090118127A1 and exemplified in Fransson et al. 2010 J Mol Biol 398:214-231, a two-step process was used to both humanize and restore or enhance binding affinity to generate the antibody species of the present invention which exhibit the target effects of the murine antibody 10H10 when engaging human TF. The two-step process, called human framework adaption (HFA), consists of 1) human framework selection and 2) an affinity maturation step.

In the HFA process, the binding site residues (CDR) are combined with human germline genes selected based on sequence similarity and structural considerations. The two systems of CDR assignments for antibodies are: the Kabat definition which is based upon antibody sequence variability and the Chothia definition based on analyses of three-dimensional structures of antibodies. Among the six CDRs, one or the other system may be used where they diverge. In the case of the light chain CDRs, the Kabat definition is used.

In the case of heavy chain CDR3, both Kabat and Chothia's definition are identical. In the case of heavy chain CDR1, the Chothia definition was used to define the start and the Kabat definition as the end (pattern defined by W followed by a hydrophobic amino acid such as V, I or A). In the case of VH-CDR2, Kabat's definition was used. However, in most antibody structures, this sequence-based definition assigns a portion of FR3 as belonging to CDR2. Thus, a shorter version of this CDR, which ends seven (7) residues earlier on the C-terminal region of this CDR could also be used, called Kabat-7 herein.

Human FR Selection

Human FR's, defined as the regions in the V regions not comprised in the antigen-binding site, were selected from the repertoire of functional human germline IGHV and IGHJ genes. The repertoire of human germline gene sequences was obtained by searching the IMGT database (Lefranc 2005) and compiling all “01” alleles. From this compilation, redundant genes (100% identical at aminoacid level) and those with unpaired cysteine residues were removed from the compilation. The last update of the gene compilation was done on Oct. 1, 2007.

Initial selection of human sequences for HFA of VH was based on sequence similarity of the human VH germline genes to the entire length of the mouse VH region including FR-1 to 3 as well as H-CDR-1 and H-CDR-2. In the next stage, the selected human sequences were rank ordered using a score that takes into account both the length of the CDRs and sequence similarities between CDRs of mouse and human sequences. A standard mutation matrix, such as the BLOSUM 62 substitution matrix (Henikoff and Henikoff 1992 Proc Natl Acad Sci USA 15; 89(22):10915-9) was used for scoring alignments of the CDR's of mouse and human sequences and a large penalty was applied if there was an insertion and/or deletion in the CDR loops. Human FR-4 was selected based on sequence similarity of the IGHJ germline genes (Lefranc 2005) with mouse 10H10 sequence, IGHJ4 (SEQ ID NO: 60).

A similar procedure was used for selecting human FRs for VL. In this case IGVK, germline genes selected using the same procedure than that used for IGHV genes, served as genes for selecting FR's 1-3 and L-CDR 1-3. Human IGJ-K2 gene (SEQ ID NO: 61) was selected as FR4 for all variants.

Eleven VH and seven VL germline chains were selected. The VH genes selected were predominantly from IGVH-1 gene family: 6 sequences from IGVH1 with IGVH1-69 and IGVH1-f used with longer and shorter H-CDR2, 2 from IGVH3, and one IGVH5 gene used with both long and short H-CDR2. The VL genes represented six of the IGVK2 and one of the IGVK4 gene family.

Thus, VH variants H15, H19 and H21 having the longer H-CDR2 (SEQ ID NO: 7) correspond to H22, H23 and H24, respectively, where the shorter mouse CDR-H2 (SEQ ID NO: 27) was used. The prefix “s” denotes test variants with fewer mouse residues and more human residues in the beta strand region. The V-region designation used and the gene sequences used are shown in Tables 2 and 3 below.

TABLE 2 Polypetide ID IMGT Gene Used H13 VH-10H10 H14 IGHV1-2 H15 IGHV5-a H16 IGHV1-46 H17 IGHV1-3 H18 IGHV3-74 H19 IGHV1-69 H20 IGHV1-18 H21 IGHV1-f H22 s1_IGHV5-a H23 s1_IGHV1-69 H24 s1_IGHV1-f

TABLE 3 Peptide ID IMGT Gene Name L1 VL-10H10 L2 IGKV4-1_B3 L3 IGKV2D40_O1 L4 IGKV2D-28_A3 L5 IGKV2D-29_A2 L6 IGKV2-30_A17 L7 IGKV2-24_A232 L8 IGKV2D-26_A21

A library of 96 Mabs, representing the 11 heavy chain and 7 light chain human FR variants plus the murine 10H10 chimeric chains was expressed in HEK 293E cells in a 96-well format to provide supernatants for the primary screen. For primary screening, using standard recombinant methods, DNA encoding the selected variable domains was recombined to form complete MAbs which were transiently expressed in 96-well plates in HEK 293E cells. Supernatant fluid from the cultures was tested for activity (binding) 96 hours following transfection.

Nineteen variants were chosen for pilot-scale expression in HEK 293-F cells and purification based on the results of the primary screen. Pilot-scale expression was done transiently in HEK 293F cells or CHO—S at a volume of 750 ml. The harvested supernatants were purified via Protein A chromatography and the purified proteins were assessed for their affinity and functional activity. In addition, the purified proteins were subjected to biophysical characterization by SDS-PAGE, SE-HPLC, and cross-interaction chromatography (CIC). Theoretical isoelectric points (pI) were calculated for each variant as well. From the pilot scale characterizations, a set of final lead candidates was transfected in WAVE bioreactors and purified via Protein A chromatography,

Binding Assessment

Binding of the parent chimeric antibody, M1, and HFA variants to both human and cyno TF was performed as a direct ELISA format using chemiluminescent detection. For primary screening of library variants in crude supernatants, samples or controls were normalized to 50 ng/ml in spent FreeStyle 293 HEK media (Gibco) and assayed at single concentration determinations. In the present assay, the concentration of antibody was 5 ng (0.1 ml used) and the TF ECD and the antigen was His6-TF-ECD₁₋₂₁₉ used at a final concentration of 10 ng/well.

The results of screening of the entire combinatorial library showed that, except H14, all other VHs bind to hTF with varying strengths. There are several HFA variants that gave a higher binding signal than the parent 10H10 (H13, L1), particularly some L3 and L5 combinations. H18 and H21 do not bind to human antigen as well as other VHs and showed insignificant binding to cyno antigen. Among the VLs, L6 and L8 did not bind either antigen while others bound at detectable levels. H14 and L8 also produced low expression when combined with any VL. There were 50 of the 77 antibody (VH, VL combinations) demonstrating TF binding as shown in Table 4.

TABLE 4 VH and VL Sequence IDs for the 50 Human TF Binding Human FR Variants Light Chain Light Chain Heavy Chain Heavy Chain Antibody ID Peptide ID SEQ ID NO: Peptide ID SEQ ID NO: M1 L1 5 H13 4 M9 L2 22 H15 12 M10 L3 23 H15 12 M11 L4 24 H15 12 M12 L5 25 H15 12 M14 L7 26 H15 12 M16 L2 22 H16 13 M17 L3 23 H16 13 M18 L4 24 H16 13 M19 L5 25 H16 13 M21 L7 26 H16 13 M23 L2 22 H17 14 M24 L3 23 H17 14 M25 L4 24 H17 14 M26 L5 25 H17 14 M28 L7 26 H17 14 M30 L2 22 H18 15 M31 L3 23 H18 15 M32 L4 24 H18 15 M33 L5 25 H18 15 M35 L7 26 H18 15 M37 L2 22 H19 16 M38 L3 23 H19 16 M39 L4 24 H19 16 M40 L5 25 H19 16 M42 L7 26 H19 16 M44 L2 22 H20 17 M45 L3 23 H20 17 M46 L4 24 H20 17 M47 L5 25 H20 17 M49 L7 26 H20 17 M51 L2 22 H21 18 M52 L3 23 H21 18 M53 L4 24 H21 18 M54 L5 25 H21 18 M56 L7 26 H21 18 M58 L2 22 H22 19 M59 L3 23 H22 19 M60 L4 24 H22 19 M61 L5 25 H22 19 M63 L7 26 H22 19 M65 L2 22 H23 20 M66 L3 23 H23 20 M67 L4 24 H23 20 M68 L5 25 H23 20 M70 L7 26 H23 20 M72 L2 22 H24 21 M73 L3 23 H24 21 M74 L4 24 H24 21 M75 L5 25 H24 21 M77 L7 26 H24 21

Based on relative binding affinity for TF using an ELISA, ten variants were selected for scale up of expression and purification. A summary of K_(D)s as measured by BIAcore, ELISA assay data, whole cell binding, inhibition of IL-8 induction from MDA-MB231 cells by 50 nM FVIIa by 2 ug/ml Mab, and Tms as measured by the Thermoflour assay are shown in Table 5.

TABLE 5 Cyno Whole IL-8 Biacore Hu TF TF Cell Induction, K_(D) (nM) EC50 EC50 Binding, Ave % MAb VH VL Human Cyno (ng/ml) (ng/ml) Ave % inhibition Tm ° C. M1 H13 L1 0.56 1.34 11.71 17.33 101% 106% 74.18 M10 H15 L3 0.77 1.57 10.47 19.63  98% 104% 75.01 M11 H15 L4 0.37 1.52 9.94 18.69 114%  93% 75.86 M12 H15 L5 0.55 2.24 10.05 22.8 124% 102% 79.72 M16 H16 L2 0.66 1.96 9.31 23.39 109% 109% 78.56 M19 H16 L5 0.41 2.81 9.22 29.61 111% 106% 77.58 M58 H22 L2 0.2 1.18 9.03 19.81  94% 106% 82.18 M59 H22 L3 0.4 1.28 8.8 18.67  95% 103% 75.94 M60 H22 L4 0.47 1.31 8.35 17.79 101% 106% 76.77 M61 H22 L5 0.21 1.71 8.3 24.07 111% 112% 81.16 M9 H15 L2 0.61 1.55 9.8 19.93 107% 106% 79.43

Several of the new human MAb variants exhibited higher affinity for TF than M1 (having the 10H10 variable chains: H13 and L1) and some were lower. The K_(D) for M61 (0.21 nM) is 2.5 times lower than that of the murine parent MAb (K_(D)=0.56 nM). The data in Table 5 includes four Mabs comprising H15 and four with H22 both constructed from the same germline gene (IGHV5-a). Those with H22, and the shorter H-CDR2, generally exhibited higher binding affinity than the corresponding molecules with H15. While many of the new variants bound cyno TF, the ranking of cyno binding affinity differed from that for binding to human TF.

The mouse 10H10 MAb Tm was 74.2° C. The Tm of the selected molecules ranged of Tms from 75 to 82.2° C. Thus, the HFA process resulted in creation of antibody constructs with new Fd regions having increased binding affinity for human and nonhuman primate TF and also produced stable complete antibody variants with human domains.

Additional characterization of the new antibody constructs verified that the antibodies were capable of recognizing native TF on cells originating from human tumor tissue (MDA-MB231 breast cancer derived cells), and reduced TF signaling in the presence of VIIa as measured by the suppressed induction of IL-8 from MDA-MB231.

Additional biophysical characterization (solubility and cross-interaction chromatography) and assay results led to the selection of M59, comprised of the variable regions H22 and L3, for affinity maturation.

EXAMPLE 4 Antibody Maturation

The Fab libraries were constructed in a pIX phage display system as described in U.S. Pat. No. 6,472,147 (Scripps) and applicants co-pending application published as WO2009/085462 with minor modifications to restriction enzyme sites.

Based on the experimental structure of 10H10 in complex with hTF, two libraries were designed starting with the M59 pairing of H116 (SEQ ID NO: 19) and L3 (SEQ ID NO: 23) for diversification of both V_(L) and V_(H). The libraries differed in terms of the positions targeted for diversification, as well as in the amino acids used to diversify targeted positions. One library diversified a total of eight of the positions representing each CDR, previously shown to be in contact with TF. The emphasis in the design was put on L1, L3, H1 and H2. Positions in contact in L2 were not diversified nor most of the positions in H3. Labile or reactive amino acids such as Cys and Met were avoided.

A second set of libraries was designed to diversify amino acids at the periphery of the antigen-binding site determined by computing the solvent accessibilities of the bound and unbound Fab crystal structure. Residues buried upon binding but also in contact with solvent molecules were targeted for diversification. A total of 12 residues (6 in V_(L) and 6 in V_(H)) were identified using this method, which were diversified with a reduced set of eight amino acids, including: Arg (R), Asn (N), Asp (D), Gly (G), His (H), Ser (S), Trp (W), and Tyr (Y). The size of the combined libraries was estimated to 8¹² or 10¹⁰ variants, which can be covered using standard library restriction cloning techniques.

For the CDR contact residue library, the positions were diversified with 15 amino acids (all except Met, Cys, Lys, Gln, and Glu) using a nucleotide dimer (N-dimer) synthetic approach.

Fab libraries displayed on phage coat protein IX were panned against biotinylated hT-ECD according to panning schemes, known in the art, directed to increasing affinity by selecting for a slower off-rate (increase in off-rate value) or faster on-rate (decrease in on-rate value), or both were used. Panning used both human and cyno TF as target antigen. Phage was produced by helper phage infection. Binders were retrieved by addition of SA-beads to form a bead/antigen/phage complex. After the final wash, phage was rescued by infection of exponentially growing TG-1 Escherichia coli cells. Phage was again produced and subjected for additional rounds of panning.

The pIX gene was excised by NheI/SpeI digestion from the selected clones and, after religation, DNA was transformed into TG-1 cells and grown on LB/Agar plates overnight. The overnight cultures were used for (i) colony PCR and sequencing for the V-regions, and (ii) soluble Fab production. The soluble Fab proteins were captured onto plates by a polyclonal anti-Fd(CH1) antibody. After appropriate washing and blocking, biotinylated hTF was added at 0.2 nM concentration and biotinylated hTF was detected by HRP-conjugated streptavidin and chemiluminescence read as before. At this concentration of hTF, ranking of the Fab variants, defined as percent binding of the parent, in which the parent Fab, present as a control in all plates is defined as 100% binding, is possible.

By this criterion, 381 Fabs binding human TF at 100% or higher relative to M59 Fab were selected.

A analysis of the selected clones, indicated certain changes at Y2, I5, T6 and Y7 of heavy chain CDR1 (SEQ ID NO:6) corresponding to positions 27 and 30-32 of the V-region (SEQ ID NO:4 or 19) were successful. Although not a contact residue, position 27 only permitted an aromatic amino acid (Tyr and Phe). For positions 30-32, which have direct contact with K68, T101, Y103 and L104 of human TF SEQ ID NO: 1 in the 10H10 Fab (FIG. 1), position 30 was relatively permissive but 31 and 32 were restricted (Table 6).

In L-CDR2 changes in L3, S6 and S8 (SEQ ID NO: 7) corresponding to positions L52, S55 and S57 of SEQ ID NO: 4 or 19, which are residues that have direct contact with P194, S195, and T197 of human TF SEQ ID NO:1 in the 10H10 Fab (FIG. 1) there was a somewhat restricted set of substitutions permitted.

In H-CDR3, the N6 position (SEQ ID NO: 8) corresponding to N104 of SEQ ID NO: 4 or 19, which makes direct contact with F147, G148 and K149 of human TF-ED (SEQ ID NO:1) appeared to be restricted.

The allowed amino acid changes in each of the library positions selected by phage panning and screening for comparable binding affinity in solid phase capture assay using 0.2 nM human TF-ECD1-219 are shown in Table 6.

TABLE 6 HC_CDR1 HC_CDR2 HC_CDR3 Contact No Yes Yes Yes Yes No Yes No Yes No Yes No with Antigen in Position Y27 I30 T31 Y32 L52 G54 S55 G56 S57 N59 N104 S105 in HC (SEQ ID NO: 19) Sequence Y I T Y L G S G S N N S Diversity F V P H I W T N Y V S A G A F V A V S W T N S H P L F L A V R A I T Y H H R F W S A L D P R Y F A D H

For VL in the selected clones, changes in S9, G10, N11 and K13 of L-CDR1 (SEQ ID NO: 9) corresponding to positions 32, 33, 34 and 36 of the LC variable region (SEQ ID NO: 5 or 23), which were shown by epitope mapping to contact E174, D129, S142, R144 and D145 of human TF SEQ ID NO:1 (FIG. 1) are shown in Table 7 as relatively permissive. For L-CDR2, residue W1, position 56 in SEQ ID NO: 5 or 23 (Kabat residue number 50), is a contact residue while residue E61 showed limited tolerability for substitution. In the light chain CDR3 (SEQ ID NO: 9) corresponding to residue positions 97-100 of SEQ ID NO: 5 or 23, which have direct contact with K149, D150, N171 and T172 of human TF SEQ ID NO:1 (FIG. 1), position D97 (Kabat position 91) was restricted. The selection based on affinity binding to human TF-ECD1-219 clone permissive amino acid usage is summarized in Table 7.

TABLE 7 LC-CDR1 LC-CDR2 LC-CDR3 Contact with Yes Yes Yes Yes Yes Yes No Yes Yes Yes Yes Antigen Position in LC S31 S32 G33 N34 K36 W56 E61 D97 Y98 T99 Y100 (SEQ ID NO: 23) Sequence A A A A A A A D A A F Diversity D F F F H G D D D H F G G G I H E F F I G H H I L W G G G L H I I L N H H H N I L L N P N I L W L N N P R P L N Y N P P R S S N R P R R S V T S S S S S T V T T T T T V Y V V V V V Y Y Y W W W Y Y Y

In summary, a series of affinity improved Fab variants were identified through construction of a phage library based on directed variegation of CDR positions of amino acid in the contact positions with antigen human TF for the variable domains H22 (SEQ ID NO: 19) and L3 (SEQ ID NO: 23), followed by panning and selection of species with affinity in the screening assay of comparable or better binding at compared to the starting sequences.

Overall, modest increases in affinity for the VH and VL pairing selected from the designed HFA libraries were obtained. However, from the VH library where contact residues were variegated, the parent amino acid was re-selected after stringent phage panning. Only two paratope positions were significantly changed, as explained from structural analysis. These two amino acid replacements introduced in the CDRs during affinity maturation, T31P and S57F, involve contact residues. The 5-fold affinity improvement may be attributed to the increased interface of F57 which is in contact with S195 of TF. The VL interaction with TF seems to be plastic, allowing many changes to contact residues as well as neighboring residues.

Of the 381 VH and VL pairings, 43 were selected for further characterization. The selected 43 MAbs represented 27 different VHs and 8 VLs (see Table 8 for the pairing of the heavy chain and light chain sequences) and could be classified into three sub-groups: Group 1 variants have the same light chain (L3, SEQ ID NO: 23), and Group 2 and Group 3 are represented by eight light chains paired with two different heavy chains (H116 and H171, SEQ ID NO: 131 and 67, respectively).

TABLE 8 LC SEQ HC SEQ MAb ID LC ID ID NO: HC ID ID NO: M1583 L3 23 H177 129 M1584 L3 23 H173 130 M1585 L3 23 H139 131 M1586 L3 23 H164 132 M1587 L3 23 H116 133 M1588 L3 23 H179 134 M1589 L3 23 H187 135 M1590 L3 23 H117 136 M1591 L3 23 H122 137 M1592 L3 23 H165 138 M1593 L3 23 H171 139 M1594 L3 23 H158 140 M1595 L3 23 H160 141 M1596 L3 23 H185 142 M1597 L3 23 H134 143 M1598 L3 23 H137 144 M1599 L3 23 H130 145 M1601 L3 23 H105 146 M1602 L3 23 H106 147 M1604 L3 23 H138 148 M1605 L3 23 H168 149 M1606 L3 23 H181 150 M1607 L3 23 H189 151 M1610 L3 23 H115 153 M1611 L3 23 H128 154 M1612 L3 23 H133 155 M1613 L3 23 H136 156 M1638 L138 157 H22 19 M1639 L320 158 H22 19 M1640 L327 159 H22 19 M1641 L335 160 H22 19 M1642 L369 161 H22 19 M1643 L162 162 H22 19 M1644 L225 163 H22 19 M1645 L283 164 H22 19 M1646 L138 157 H171 139 M1647 L320 158 H171 139 M1648 L327 159 H171 139 M1649 L335 160 H171 139 M1650 L369 161 H171 139 M1651 L162 162 H171 139 M1652 L225 163 H171 139 M1653 L283 164 H171 139

Of the group of 27 antibodies having the same light chain as M59 (L3, SEQ ID NO: 23), the 27 heavy chains differ at three positions in H-CDR1 (GYTFX₁X₂X₃WIE (SEQ ID NO: 83) where X1 is selected from A, D, G, I, L, N, P, R, S, T, V, Y and X2 is selected from A, P, S, and T and X3 is selected from F, H, and Y); except in H189 where H-CDR1 is GFTFITYWIA (SEQ ID NO: 81), and at four positions in H-CDR2 (DIX₁PGX₂GX₃TX₄ (SEQ ID NO: 107) where X1 is selected from 1 and L, X2 is selected from S and T, X3 is selected from A, F, H, and w; and X4 is selected from D, H, I, L, and N; except in H189 where H-CDR2 is DILPASSSTN (SEQ ID NO: 105)) while the H-CDR3 and FRs were unaltered from the H22 sequence (SEQ ID NO: 19) and is SGYYGNSGFAY (SEQ ID NO: 8). The unique compositions of the heavy chains for these 27 Mabs are given below (Table 9).

TABLE 9  SEQ ID NO: SEQ ID NO: LC SEQ HC HC SEQ for for MAb  ID NO: ID  ID NO: HC-CDR 1 H-CDR1 HC-CDR 2 H-CDR2 M1583 23 H177 129 GYTFGPYWIE 82 DIIPGSGWTN 100 M1584 23 H173 130 GYTFVTYWIE 77 DILPGTGYTV 99 M1585 23 H139 131 GYTFSPFWIE 70 DIIPGTGYTN 93 M1586 23 H164 132 GYTFPTYWIE 73 DIIPGTGWTN 95 M1587 23 H116 133 GYTFIPYWIE 63 DILPGSGFTT 86 M1588 23 H179 134 GYTFGPFWIE 78 DILPGSGYTN 101 M1589 23 H187 135 GYTFGPHWIE 80 DILPGTGYTN 104 M1590 23 H117 136 GYTFLPYWIE 64 DIIPGTGFTN 88 M1591 23 H122 137 GYTFRPYWIE 65 DIIPGTGYTN 93 M1592 23 H165 138 GYTFSPHWIE 74 DILPGSGYTI 96 M1593 23 H171 139 GYTFAPYWIE 67 DILPGTGFTT 98 M1594 23 H158 140 GYTFPPYWIE 72 DILPGTGYTV 99 M1595 23 H160 141 GYTFYPYWIE 72 DILPGTGFTN 94 M1596 23 H185 142 GYTFTPYWIE 68 DILPGSGHTT 103 M1597 23 H134 143 GYTFSSYWIE 70 DILPGTGATH 90 M1598 23 H137 144 GYTFTPYWIE 68 DILPGTGYTV 99 M1599 23 H130 145 GYTFGPYWIE 82 DILPGTGYTL 89 M1601 23 H105 146 GYTFGPYWIE 82 DILPGTGYTV 99 M1602 23 H106 147 GYTFDAHWIE 62 DILPGSGFTD 84 M1604 23 H138 148 GYTFAPYWIE 76 DILPGTGYTW 92 M1605 23 H168 149 GYTFGTYWIE 75 DILPGTGHTT 97 M1606 23 H181 150 GYTFIPHWIE 79 DILPGSGWTN 102 M1607 23 H189 151 GFTFITYWIA 81 DILPASSSTN 105 M1610 23 H115 153 GYTFAPYWIE 76 DIIPGTGYTT 85 M1611 23 H128 154 GYTFGPYWIE 82 DILPGSGYTT 88 M1612 23 H133 155 GYTFNPYWIE 66 DILPGTGYTN 104 M1613 23 H136 156 GYTFSSHWIE 69 DILPGSGFTH 91

H171 (SEQ ID NO: 139) comprises an additional change in H-CDR1 and H-CDR2 as compared to H116, which are I31A and S55T.

Two groups of Mabs are represented by eight LC (Table 10) paired with one of two different HC: H22 (SEQ ID NO: 19) or heavy chain H171 (SEQ ID NO: 139). The eight light chains all have the FR of L3 (derived from IGKV240_O1) and have sequence changes in five positions in L-CDR1 (KSSQSLLX₁X₂X₃X₄QX₅NYLT (SEQ ID NO: 116) where X1 is selected from F, P, S, T, W, and Y; X2 is selected from F, S, T, R, and V; X3 is selected from A, G, P, S, W, Y, AND V; X4 is selected from G, N, and T; X5 is selected from K, R, and S), two in L-CDR 2 (X₁ASTRX₂S (SEQ ID NO: 120) where X1 is selected from H and W; X2 is selected from D, E and S) and four in L-CDR3 (QNDX₁X₂X₃PX₄T (SEQ ID NO: 128) where X1 is selected from D, F, and L; X2 is selected from S, T, and Y; where X3 is selected from W, and Y; X4 is selected from L, and M). The compositions of the eight LC are shown in Table 10.

TABLE 10 LC SEQ ID NO: SEQ ID NO: SEQ ID NO: LC SEQ for L-CDR1 for L-CDR2 for L-CDR3 ID ID NO: L-CDR1 Sequence L-CDR2 Sequence L-CDR3 SEQUENCE L138 156 108 KSSQSLLWFV 117 HASTRES 122 QNDDSYPL NQKNYLT T L162 161 109 KSSQSLLYVY  10 WASTRES 121 QNDFSWPL GQKNYLT T L225 162 110 KSSQSLLFRP  10 WASTRES 122 QNDDSYPL TQKNYLT T L283 163 111 KSSQSLLYTS  10 WASTRES 123 QNDDYWPL NQKNYLT T L320 157 112 KSSQSLLYSG 118 WASTRSS 124 QNDDTYPM NQRNYLT T L327 158 113 KSSQSLLPSW  10 WASTRES 125 QNDFTYPL NQSNYLT T L335 159 114 KSSQSLLFSA 119 WASTRDS 126 QNDDTYPL NQRNYLT T L369 160 115 KSSQSLLTSY  10 WASTRES 127 QNDLTYPL NQRNYLT T

Some of these Mabs were subjected to further characterization and tested in in vivo xenograft models (Example 5).

EXAMPLE 5 Characterization of Mabs

Following the human framework adaptation and reselection of a library of variants based on M59 comprising a single LC variable region (L3, SEQ ID NO. 23) and single HC variable region (H22, SEQ ID NO: 19), with altered residues in some CDR residues, the novel Mabs were subjected to biophysical and bioactivity assays, and one paring, M1587, with altered paratope residues was used to re-examine whether the epitope originally characterized for a 10H10 Fab binding to TF-ECD (Example 2) was altered.

Human TF ECD: M1587 Interface

The co-crystallization of human-adapted and affinity matured antibody based on 10H10 CDRs, M1587 (L3 and H116) with TF ECD was performed in the same manner as for 10H10 (Example 3) except that the M1587-Fab:TF complex was crystallized from solution containing 16% PEG 3350, 0.2 M ammonium acetate, 0.1 M sodium acetate, pH 4.5.

Comparison of the co-crystal structure of human TF ECD with that with the affinity matured M1587 Fab indicates that the human adaptation and affinity maturation of 10H10 has not changed the antibody epitope footprint as shown in FIG. 2, nor have the conformation of the CDRs been altered. Three amino acid replacements (T31P, S57F, and N59T) were introduced in H-CDR1 and H-CDR2 (SEQ ID NO: 6 and 27, respectively, using the CDR definitions described in Example 2) during human framework adaption and affinity maturation (SEQ ID NO: 6 and 7 were replaced with SEQ ID NO: 63 and 86) including the contact residues at residue 31 and 57 of H116 (SEQ ID NO: 133) which are T31P and S57F. There was a five-fold affinity improvement that may be attributed to the increased interface of F57, which is in contact with S195 of TF. The structure of human TF ECD with M1587 Fab confirmed the preservation of the epitope during HFA and affinity maturation even though changes were made in the H-CDR1 and H-CDR2 paratope residues.

Biophysical and Biological Assay Results

Summary data for these antibodies is show below for the KD analysis by Biacore (Table 11), coagulation time of human plasma by human TF (Table 12), and the EC50 for IL8 release from MD-MB-231 cells stimulated with FVIIa (Table 13, 14, and FIG. 5).

The K_(D) for 43 selected affinity matured Mabs and includes data generated for the murine 10H10 and chimeric version of that MAb (M1) with selected human framework adapted variants with unmodified CDR from 10H10 (M numbers less than 100) are shown in Table 11. Thus, the combination of human framework selection and CDR residue substitution produced human antibodies with K_(D) in the range of 80 to 950 μM with an off rate (Koff) in the range of 2.2×10⁻⁵ sec-1 to 2.6×10⁻³ sec-1; and with an on rate (Kon) in the range of 10⁴ M-1 sec-1 to 2.3×10⁵ M-1 sec-1. Compared to values for the original murine 10H10 or the chimeric construct, the novel Mabs have up to a 10-fold lower in equilibrium dissociation constant (K_(D)), from 0.77 nM to 0.08 nM; display a faster on rate (K_(on)>10⁵ M-1 sec-1), or have a slower off rate (Koff=10⁵ sec-1). These properties can be used to advantage in selecting a MAb for particular applications where either residence time or ability to penetrate tissues is desired.

TABLE 11 ka kd Antibody (1/Ms) (1/s) K_(D) ID 10⁴ 10⁻⁴ (nM) M1639 4.69 3.71 0.08 M1645 5.21 4.12 0.08 M1647 3.87 4.02 0.1 M1652 4.44 4.82 0.11 M1641 4.56 5.46 0.12 M1644 5.81 7.19 0.12 M1587 15.7 0.23 0.14 M1604 15.2 0.22 0.14 M1653 2.31 3.76 0.16 M1649 3.85 6.46 0.17 M1593 13.8 0.25 0.18 M1606 16.55 0.29 0.18 M1643 4.52 8.13 0.18 M1646 3.5 6.47 0.19 M1650 2.33 4.5 0.19 M1651 2.01 3.88 0.19 M58 9.48 0.18 0.19 M1638 4.89 9.92 0.2 M61 9.41 0.19 0.2 M1584 18.4 0.56 0.3 M1611 19.2 0.59 0.31 M1596 13.1 0.43 0.33 M1598 19.2 0.63 0.33 M1601 13.7 0.46 0.33 M1588 17.3 0.6 0.35 M1594 12.4 0.43 0.35 M1607 17 0.6 0.35 M11 9.73 0.35 0.36 M1612 16.5 0.63 0.38 M1595 17.6 0.68 0.39 M1599 13.8 0.53 0.39 M1589 17.4 0.7 0.4 M1592 19.1 0.77 0.4 M1591 13.4 0.56 0.41 M19 9.88 0.41 0.41 M59 9.33 0.38 0.41 M1583 23.9 1 0.42 M60 9.75 0.46 0.47 M1585 18.5 0.9 0.49 M46 9 0.44 0.49 M1610 18.4 1 0.54 M37 6.9 0.37 0.54 M12 9.22 0.51 0.55 M9 9.73 0.59 0.61 M1602 13.2 0.82 0.62 M1605 13.5 0.86 0.64 M16 10.2 0.67 0.66 M1590 15.9 1.09 0.69 M1648 1.02 7.45 0.73 M1640 1.02 7.8 0.76 10H10 8.88 0.68 0.76 M1 9.52 0.74 0.77 M10 9.26 0.71 0.77 M1586 18.4 1.43 0.78 M1597 8.34 0.66 0.8 M1613 7.57 0.7 0.92 M1642 2.74 26.1 0.95 M42 8.04 0.82 1.02 M26 8.26 0.93 1.13 M68 6.43 1.03 1.6 M51 8.11 2.35 2.9 M52 7.4 2.64 3.57 Coagulation

The novel Mabs are characterized by the ability to bind human TF without blocking coagulation of human plasma as measured in vitro in the presence of calcium and exogenously added human TF (Table 12). Seventeen HFA (M number less than 100) variants and 38 affinity maturated variants (M1583 and above) were assayed and the T_(1/2), Max (the time in seconds to reach 50% of the maximum optical density) reported.

All demonstrate responses similar to that observed with 10H10 (Table 12) with T_(1/2), Max values less than 205 seconds, indicating these antibodies do not prolong the coagulation time when compared to the vehicle control with no antibody which was 159±17 (n=14). CNTO860, a human TF binding antibody described previously (U.S. Pat. No. 7,605,235 B2) and derived from the murine antibody 5G9 which blocks FX binding to TF, prolongs clotting and never reaches coagulation within 1800 sec in the same assay. Five of the 43 MAbs described in Example 4 as having altered CDRs, were not tested in the coagulation assay because they have starting concentration less than 2 mg/ml. M1, M59 and CNTO860 values were averaged over multiple tests.

TABLE 12 T½ Max (seconds) SD MAb ID (n = 2) (seconds) 10H10* 191 2 M1* 173 5 CNTO860* >900 11 M9 198 3 M10 196 6 M11 195 5 M12 197 7 M16 198 5 M19 199 5 M26 186 4 M37 196 5 M42 202 7 M46 195 6 M51 207 7 M52 201 6 M58 192 5 M59* 169 4 M60 180 4 M61 186 10 M68 207 11 M1583 189 8 M1584 199 6 M1585 205 12 M1586 200 7 M1587 202 10 M1588 207 10 M1589 202 3 M1590 180 5 M1591 154 6 M1592 163 6 M1593 164 7 M1594 165 5 M1595 163 5 M1596 163 5 M1597 157 6 M1598 155 4 M1599 151 6 M1601 180 6 M1602 163 7 M1604 165 5 M1605 160 5 M1606 157 5 M1607 152 6 M1610 164 4 M1611 154 10 M1612 163 11 M1613 165 11 M1638 163 12 M1639 167 5 M1640 168 9 M1641 162 9 M1642 166 6 M1643 148 6 M1644 150 6 M1645 154 4 M1647 160 6 M1648 161 3 M1650 150 6 Signal Blocking Activity

The novel MAbs can also be described in terms of their ability to block signaling through the TF/FVIIa complex. TF/VIIa/PAR2 signaling of breast cancer cells induces a broad repertoire of proangiogenic factors such as VEGF25, Cyr61, VEGF-C, CTGF, CXCL1, and IL-8. It was previously reported that FVIIa induces detectable IL-8 in MDA-MB-231???, a human breast cancer cell line expressing TF (Albrektsen et al., J Thromb Haemost 5: 1588-1597, 2007). Therefore, this assay was used as a biological assay to evaluate the variant antibodies ability to inhibit TF/VIIa induction of IL-8 production.

The details of the assay are given herein above and the results of testing 19 of the HFA (M10-M68) variants of Example 3 and 29 of the CDR variants of Example 4 were tested for the ability to inhibit IL-8 production at a single concentration of TF (0.5 microgm per ml). An anti-RSV antibody (B37) that does not bind Tissue Factor, used as a negative control. At this concentration, many of the HFA Mabs were able to block IL-8 induction by more than 67% (Table 13). FIG. 5 shows the relative inhibition of IL8-release by 27 of the MAbs sharing the L3 light chain (SEQ ID NO: 23) and having substitutions in H-CDR1 or H-CDR2 as compared to those of 10H10 (SEQ ID NO: 6 and 7, respectively). In addition; four of these: M1584, M1611, TF7M1612 and TF7M1607 were placed in a full titration IL-8 induction assay along with M. The relative IC50 values calculated further support the observation that the affinity improved variants are more potent as compared to M1, the mouse-human chimera of 10H10 (Table 14). The other affinity mature groups of affinity maturated antibodies described in Example 4 produced similar results.

TABLE 13 Variants % IL-8 ID Inhibition SD 10H10 93.9 8.0 M1 96.1 7.6 M9 102.7 4.5 M10 90.7 0.0 M11 87.9 9.4 M12 98.6 3.1 M16 98.3 6.2 M19 87.3 5.8 M26 79.1 1.3 M37 71.2 11.6 M42 86.0 20.1 M46 82.5 10.7 M51 71.5 9.4 M52 67.7 4.0 M58 88.5 8.5 M59 83.8 8.0 M60 99.6 4.5 M61 106.8 4.9 M68 89.8 11.1

TABLE 14 MAb ID IC50 (ug/ml) M1 0.527 M59 0.382 M1584 0.332 M1607 0.395 M1611 0.398 M1612 0.413

EXAMPLE 6 Antibody Antitumor Activity

Mouse Xenograft Model with MDA-MB-231

MDA-MB-231 human breast cancer cells were cultured in DMEM medium with 10% FBS and 1% LNN, harvested at log phase by trypsinization, and resuspended in sterile serum-free DMEM media at 5×10⁷ cells/mL. Twenty female SCID Beige (C.B-17/IcrCrl-scid-bgBR) mice were obtained from Charles River Laboratories and acclimated for 14 days prior to experimentation. At approximately eight weeks of age, mice were implanted in the right axillary mammary fat pad with 2.5×10⁶ MDA-MB-231 cells. When tumors were approximately 100 mm³ in size, mice were stratified by tumor size into treatment groups (N=10 per group). Intraperitoneal treatment with Dulbecco's Phosphate Buffered Saline (DPBS) or M1593 at 10 mg/kg of body weight, commenced on the day of stratification, and continued once weekly for a total of six doses. Tumors and body weights were recorded once weekly. The study terminated when the mean tumor volume of each group reached 1500 mm³. Statistical tests applied were two-way repeated measures ANOVA (PRIZM 4.0, GraphPad).

In MDA-MB-231 xenograft model, M1593 significantly inhibited tumor growth beginning on Day 22 (*P<0.01) and continuing until Day 29 (**P<0.001), at which point the control (DPBS-treated) group was euthanized. The M1593 treated group was euthanized on Day 36. M1593 inhibited tumor growth by approximately 49% on Day 29. There was an approximately 11-day tumor growth delay in the M1593 treated group, relative to the DPBS-treated control group (FIG. 6).

Mouse Xenograft Model with A431

A431 human squamous cell carcinoma cells were cultured in DMEM medium with 10% FBS and 1% LNN, harvested at log phase by trypsinization, and resuspended in sterile HBSS at 1×10⁷ cells/mL. Twenty female SCID Beige (C.B-17/IcrCrl-scid-bgBR) mice were obtained from Charles River Laboratories and acclimated for 14 days prior to experimentation. At approximately eight weeks of age, mice were implanted in the right flank with 2×10⁶ A431 cells. When tumors were approximately 118 mm³ in size, mice were stratified by tumor size into treatment groups (N=10 per group). Intraperitoneal treatment with DPBS or M1593 at 10 mg/kg of body weight, commenced on the day of stratification, and continued once weekly for a total of six doses. Tumors and body weights were recorded twice weekly. The study terminated when the mean tumor volume of each group reached 1000 mm³ Statistical tests applied were two-way repeated measures ANOVA (PRIZM 4.0, GraphPad).

M1593 significantly inhibited tumor growth on Day 22 (*P=0.0067), at which point the control (DPBS treated) group was euthanized. The CNTO592-treated group was euthanized on Day 39. CNTO592 inhibited tumor growth by approximately 54% on Day 22. There was an approximately 17-day tumor growth delay in the M1593 treated group, relative to the DPBS-treated control group (FIG. 7).

EXAMPLE 7 Antibody Compositions with Altered F_(C)

Naturally occurring human Fc receptor variants have substantially differing affinities for the Fc-portion of human antibodies. In addition, clinical studies have demonstrated improved response rates and survival for patients with tight binding Fc genotypes after treatment with Fc-engineered mAbs (Musolino et al 2008 J Clin Oncol 26:1789-1796 (2008); Bibeau et al 2009 J Clin Oncol 27:1122-1129).

While inhibition of TF signaling is expected to reduce cellular responses leading to tumor proliferation, migration, and metastasic spread, the fact that TF antigen is displayed on tumor cells provides for a means for selective killing of the target cell by mechanisms related to Fc-receptor engagement by the antibody Fc. The surface features of the Fc-domain of the antibody are known to be influenced by the glycan composition as well as the primary sequence of the heavy chains, and modification of either or both can alter Fc-receptor binding.

The MAb identified as M1593, was produced as a low fucose glycan-modified IgG1 and also as a IgG1-CH2 domain variant (S239D, 1332E where the numbering is that of Kabat EU system).

MAb Compositions and Methods of Making

The antibody with low fucose content (M1593-LF) was produced by electroporating a vector encoding the M1593 (IgG1/Kappa) chains as shown below with signal peptides into a CHO host cell subline selected for low fucosylation of proteins from the CHO host cell line. SEQ ID NO: 165 represents the complete light chain comprising the variable domain, residues 1-113 (SEQ ID NO: 23 plus FR4, SEQ ID NO: 61, underlined) and the human kappa constant light domain. The heavy chains comprising the variable domain residues 1-120 (which includes SEQ ID NO: 139 and FR4 SEQ ID NO: 60, underlined) with wild-type human IgG isotype1 CH1, CH2, and CH3 where the Kabat positions 239 and 332 (which are 242 And 335 of SEQ ID NO: 167) are modified from the wild-type residues S and D, to D and E, respectively to form the variant M1593-DE.

M1593-Light Chain (SEQ ID NO: 165) DIVMTQTPLSLPVTPGEPASISCKSSQSLLSSGNQKNYLTWYLQKPGQSPQLLIYWA STRESGVPDRFSGSGSGTDFTLKISRVEAEDVGVYYCQNDYTYPLTFGQGTKLEIKR TVAAPSVFIFPPSDEQLKSGTASVVCLLNNFYPREAKVQWKVDNALQSGNSQESVT EQDSKDSTYSLSSTLTLSKADYEKHKVYACEVTHQGLSSPVTKSFNRGEC M1593-heavy chain where Kabat position S239 is D, and I332 is E (SEQ ID NO: 167) EVQLVQSGAEVKKPGESLRISCKGSGYTFAPYWIEWVRQMPGKGLEWMGDILPGT GFTTYSPSFQGHVTISADKSISTAYLQWSSLKASDTAMYYCARSGYYGNSGFAYWG QGTLVTVSSASTKGPSVFPLAPSSKSTSGGTAALGCLVKDYFPEPVTVSWNSGALTS GVHTFPAVLQSSGLYSLSSVVTVPSSSLGTQTYICNVNHKPSNTKVDKKVEPKSCDK THTCPPCPAPELLGGP D VFLFPPKPKDTLMISRTPEVTCVVVDVSHEDPEVKFNWYV DGVEVHNAKTKPREEQYNSTYRVVSVLTVLHQDWLNGKEYKCKVSNKALPAP E E KTISKAKGQPREPQVYTLPPSRDELTKNQVSLTCLVKGFYPSDIAVEWESNGQPENN YKTTPPVLDSDGSFFLYSKLTVDKSRWQQGNVFSCSVMHEALHNHYTQKSLSLSPG K

The CHO cell was generated by sub-cloning after four rounds of negative lectin selection (selection of non-binding to fucose binding lectin) and FACS sorting to isolate a pool of naturally occurring low fucose cells to be used as a host cell line. This line was derived from the same host cells used to produced M1593 and therefore, the cells are cultured and handled exactly in the same manner. Transfected cells were screened by methylcellulose plating using protein G for detection and colonies picked into 96-well plates. Cultures were expanded to shaker flasks for titering. Top parental clones produced M1593-LF up to 708 mg/L (in standard medium) in batch shake flask cultures.

LC-MS glycopeptide mapping was performed on two M1593-LF producing clones (C2452B and C2452D) to determine the percent fucosylation and evaluate the stability of the glycosylation profile over time and production process (Table 15). Samples were collected during a stability study from passage 1 fed-batch and passage 10 batch cultures and purified. Purified samples from the bioreactor evaluation were also analyzed. Glycopeptide mapping showed favorable glycosylation patterns with low percent total fucosylation from C2452B and C2452D. Importantly, the percent fucosylation did not significantly increase over time which suggests that the host cell fucosylation is stable. Thus, the fucose content for M1593-LF is less than 10%, and generally, less than 5% and, in some preparations, less than 2%. Mab produced in the non-lectin selected host CHO cell comprised glycan groups where greater than 80% were fucosylated.

TABLE 15 Clone % Fucosylation Sample Analyzed C2452B 2.81 P1 Shake Flask Fed-batch C2452B 1.83 p10 Batch of Stability Study C2452B 3.67 Bioreactor C2452D 2.20 P1 Shake Flask Fed-batch C2452D 2.25 p10 Batch of Stability Study C2452D 7.31 Bioreactor

For the mutant Fc variant of M1593 (M1593-DE), the plasmid expressing M1593 was subjected to site directed mutagenesis.

Biological Activity

The three anti-human TF Fc variants (M1593, M1593-LF, and M1593-DE) affinity for both human and cynomolgus Fc receptors (FcγRI, FcγRIIa, FcγRIIIa). These assays were performed as described in applicants co-pending application (U.S. Ser. No. 61/426,619) or by using Plasmon resonance (Biacore) based binding assays (?).

The results of these assays demonstrated that both Fc modified anti-TF antibodies bound much more tightly to recombinant human FcγIIIa receptors compared with the parental, unmodified IgG1 M1593 antibody by 18-fold (M1593-LF) and 40-fold (M1593-DE) (Table 16).

TABLE 16 Anti-TF antibody affinities for human FcγIIIa receptors MAb Human Fcγ111a K_(D) (M) M1593 (wild-type human IgG1/kappa 2.1 × 10⁻⁷ constant domains) M1593-DE (hIgG1 with S239D/I332E) 5.0 × 10⁻⁹ M1593-LF (hIgG1 produced in host subline 1.2 × 10⁻⁸ producing reduced fucosylation in glycans)

ADCC is stimulated by FcγRIIIa engagement. ADCC assays were performed as previously described (Scallon et al., Mol Immunol 44:1524-1534 2007).

Improved Fc receptor binding was reflected in functional in vitro ADCC assays using human PBMC as effector cells and human breast cancer cell line MDA-MB-231 as the target cell (FIG. 8). 

What is claimed:
 1. An isolated anti-tissue factor antibody comprising: three heavy chain CDR sequences, H-CDR1, H-CDR2, and H-CDR3, represented by SEQ ID NOs: 72, 94, and 8, respectively, and three light chain CDR sequences, L-CDR1, L-CDR2 and L-CDR3, represented by SEQ ID NOs: 9-11, respectively.
 2. The isolated antibody of claim 1, wherein the antibody does not compete with FVIIa for tissue factor binding and does not substantially block the procoagulant, amidolytic activity of the TF-VIIa complex but which does block TF-VIIa mediated signaling as measured by cytokine IL-8 release from MDA-MB-231 cells.
 3. The antibody of claim 1, wherein the human HC variable region frameworks are derived from an IGHV family 1, 3 or 5 member as represented by the IMGT database.
 4. The antibody of claim 1, wherein the human LC variable region frameworks are derived from a human IGKV family two or four member.
 5. The antibody of claim 1, wherein the human HC variable region frameworks are derived from a human germline gene family selected from IGHV5 and IGKV2.
 6. The isolated antibody of claim 1, having an IgG1 or IgG4 isotype.
 7. The isolated antibody of claim 1, wherein the Fc region comprises human IgG1 isotype where the Kabat positions 239 and 332 (which are 242 and 335 of SEQ ID NO: 167) are modified from the wild-type residues S and D, to D and E mutations in the Fc region.
 8. A pharmaceutical composition comprising an antibody of claim
 1. 9. An isolated anti-tissue factor antibody comprising an antibody heavy chain variable domain of SEQ ID NO:
 141. 10. The antibody of claim 9, further comprising an antibody light chain variable domain of SEQ ID NO:
 23. 11. The isolated antibody of claim 9, wherein the antibody does not compete with FVIIa for tissue factor binding and does not substantially block the procoagulant, amidolytic activity of the TF-VIIa complex but which does block TF-VIIa mediated signaling as measured by cytokine IL-8 release from MDA-MB-231 cells.
 12. The antibody of claim 9, wherein the human LC variable region frameworks are derived from a human IGKV family two or four member.
 13. The isolated antibody of claim 9, having an IgG1 or IgG4 isotype.
 14. The antibody of claim 9, wherein the LC human FR sequences are derived from IGKV2D40_O1 and the LC variable region has the sequence selected from SEQ ID NO: 23, 157-164.
 15. A pharmaceutical composition comprising an antibody of claim
 9. 